`
`LG Electronics Ex. 1032
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 1 of 20
`
`5,944,405
`
`0
`
`.
`
`LGE_001108
`
`LGE_001108
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 2 of 20
`
`5,944,405
`
`42
`
`4
`
`/
`
`4:
`
`FIG. 4
`
`LGE_001109
`
`LGE_001109
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 3 of 20
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`5,944,405
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`42
`
`/4
`
`42
`
`/4
`
`42
`
`/4
`
`/4
`
`FIG. 5
`
`FIG. 6
`
`FIG. 7
`
`42
`
`FIG. 8
`
`42
`
`4
`
`LGE_001110
`
`LGE_001110
`
`
`
`U.S. Patent
`
`Aug. 31, 1999
`
`Sheet 4 of 20
`
`5,944,405
`
`LGE_001111
`
`LGE_001111
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 5 of 20
`
`5,944,405
`
`LGE_001112
`
`LGE_001112
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 6 of 20
`
`5,944,405
`
`LGE_001113
`
`LGE_001113
`
`
`
`U.S. Patent
`
`Aug. 31, 1999
`
`Sheet 7 of 20
`
`5,944,405
`
`(°/o)
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`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 8 of 20
`
`5,944,405
`
`CUMULATIVE
`FREQUENCY
`DISTRIBUTION (°/o)
`0
`IOO
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`HEIGHT OF
`IRREGULARITIES
`(ABSOLUTE VALUE)
`57.7 (*‘"‘)
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`IRREGULARITIES
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`FIG. 2|
`
`LGE_001115
`
`
`
`U.S. Patent
`
`Aug. 31, 1999
`
`Sheet 9 of 20
`
`5,944,405
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`OOmuN
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`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 10 of 20
`
`5,944,405
`
`CUMULATNE
`FREQUENCY
`DISTRIBUTION (%)
`0
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`IOO
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`(ABSOLUTE VALUE)
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`FIG. 23
`
`LGE_001117
`
`LGE_001117
`
`
`
`LGE_001118
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 12 of 20
`
`5,944,405
`
`CUMULATIVE
`FREQUENCY
`
`DISTRIBUTION (%)
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`0
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`
`FIG. 25
`
`LGE_001119
`
`LGE_001119
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 13 of 20
`
`5,944,405
`
`IVIAGNIFICATIONx:IOO,Y:I00.2:500
`
`FIG.26
`
`LGE_001120
`
`LGE_001120
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 14 of 20
`
`5,944,405
`
`CUMULAHVE
`FREQUENCY
`DISTRIBUTION (%)
`0
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`HBGHT OF
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`20.3 (/Am)
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`F I G. 28
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`LGE_001121
`
`LGE_001121
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 15 of 20
`
`5,944,405
`
`CUMULATIVE
`FREQUENCY
`DISTRIBUTION (%)
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`HEIGHT OF
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`F I G. 29
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`LGE_001122
`
`LGE_001122
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 16 of 20
`
`5,944,405
`
`MAGNIFICATIONx:IOO,Y:I00,2:uooo FIG.30
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`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 17 of 20
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`5,944,405
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`LGE_001124
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`LGE_001124
`
`
`
`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 18 of 20
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`5,944,405
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`U.S. Patent
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`Aug.31, 1999
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`Sheet 19 of 20
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`5,944,405
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`LGE_001126
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`U.S. Patent
`
`Aug.31, 1999
`
`Sheet 20 of 20
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`5,944,405
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`5,944,405
`
`1
`FLAT LIGHT SOURCE USING LIGHT-
`DIFFUSING SHEET WITH PROJECTIONS
`THEREON
`
`TECHNICAL FIELD
`
`The present invention relates to a flat light source that can
`be used in applications such as back-lighting for a light
`transmissive type of display device such as a liquid crystal
`display device, an illuminated advertisement, or a traffic
`sign. In particular, it relates to a flat light source that uses a
`light-diffusing sheet.
`
`BACKGROUND OF THE INVENTION
`
`light sources that are used for back-lighting in
`Flat
`devices such as liquid crystal displays (LCDs) are known in
`the art, as described below.
`Afirst known type of flat light source is an edge-lit system
`that uses a flat optically transmissive plate as an optically
`conductive member. The flat light source used in this system
`causes light to be incident on one or both side edge surfaces
`of the optically conductive member which is formed of a
`transparent flat plate. Total reflection within the flat optically
`transmissive plate is utilized to propagate the light through-
`out the entire optically conductive plate. Part of the thus
`propagated light becomes diffused reflected light of less than
`the critical angle from a light-scattering reflective plate on
`the rear surface of the optically conductive plate, and thus
`diffused light
`is emitted from the outer surface of the
`optically conductive plate (refer to Japanese Utility Model
`Laid Open No. 55-162,201).
`A second known type of flat light source has a lens sheet
`wherein one surface has projections and the other surface is
`smooth, which is placed with the projection side thereof on
`the outer surface of the optically conductive plate of the flat
`light source of the above first type. The light-focusing action
`of this lens is utilized to ensure that the diffused, reflected
`light is diffused uniformly and isotropically within a prede-
`termined angular range (refer to Japanese Utility Model Laid
`Open No. 4-107,201).
`The above described lens sheet could be used in combi-
`
`nation with a frosted transparent diffusion plate (a frosted
`transparent sheet) formed by dispersing particles of a light-
`diffusing agent such as TiO2 within a transparent plastic. In
`such a case,
`the optical energy of the light source is
`distributed in a more concentrated manner within a prede-
`termined limited angular range, than when a frosted trans-
`parent diffusion plate alone is placed over the optically
`conductive plate (refer to U.S. Pat. No. 4,729,067 and
`Japanese Patent Laid Open No. 61-55,684). Moreover, a
`uniform and highly isotropic diffused light can be obtained
`within this angular range.
`However, both of the above prior-art techniques have
`problems. The first one simply places a light-scattering
`reflective plate on the rear surface of the optically conduc-
`tive plate so that the emitted light has a comparatively sharp
`distribution that peaks at an angle of 60 degrees to the
`normal of the surface of the optically conductive plate.
`Therefore a phenomenon is observed in which the degree of
`luminance is insufficient in the normal direction (the forward
`direction) where brightness is most required, while optical
`energy is wasted in the lateral directions where it is com-
`pletely unnecessary.
`The second prior-art technique has a problem in that,
`when a lenticular sheet that comprises an array of a large
`number of individual triangular prismatic lenses is super-
`
`10
`
`15
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`20
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`25
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`30
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`2
`imposed on the light-emitting surface of the optically con-
`ductive plate as the lens sheet, the ratio of optical energy
`emitted within angles between 30 and 60 degrees from the
`normal to the light-emitting surface is comparatively high,
`but even if the portion within 2 to 4 cm of the side edge
`portion of the optically conductive plate is very bright, the
`luminance drops gradually further away from this portion so
`that the edge at the opposite side from the light source is
`noticeably darker.
`If a frosted transparent scattering diffusion plate is used,
`a further problem arises in that the particles of light-diffusing
`agent within the optically conductive plate absorb some of
`the light, so that the optical energy thereof is lost.
`In addition, interference patterns such as Newton’s rings
`could be generated by the optical seal between the lens sheet
`and the surface of the optically conductive plate.
`Techniques that have been tried to solve these problems
`include:
`
`1. An attempt to correct and make uniform the luminance
`distribution within the surface of the optically conductive
`plate by creating a pattern in a light-scattering reflective
`layer on the rear surface of the optically conductive plate,
`such as a dot pattern, in such a manner that the surface area
`of the pattern is decreased closer to the light source and
`increased further away therefrom, as disclosed in Japanese
`Patent Laid-Open No. 1-245,220 and Japanese Utility Model
`Laid-Open No. 6-15,008.
`2. An attempt to correct and make uniform the luminance
`distribution within the surface of the optically conductive
`plate by disposing two or more light sources at the side edge
`portions of the optically conductive plate, as disclosed in
`Japanese Patent Laid-Open No. 3-9306.
`3. An attempt to obtain a directed output light that has a
`substantially uniform luminance from the entire surface of
`the optically conductive plate, by providing a linear pris-
`matic array (an array of prismatic lenses) that partially
`reflects and partially passes light on either the front or rear
`surface of the optically conductive plate, and varying the
`angle of inclination of the surfaces of these prisms and
`locally varying the thickness of the optically conductive
`plate, as disclosed in Japanese Patent Laid-Open No.
`62-3226.
`
`All of the above measures, and others, have problems in
`that it is difficult to provide a completely uniform luminance
`thereby. In addition, technique 1 has a further problem in
`that the dot pattern of the light-scattering reflective layer is
`visible from the side from which light is emitted. Technique
`2 has a further problem in that the space required for the
`entire light source and the power consumption thereof are
`more than doubled.
`
`Technique 3 has problems in that the form of the optically
`conductive plate is complicated,
`the fabrication of this
`design is extremely difficult, and it is also difficult to make
`the dot pattern of the light-scattering reflective layer invis-
`ible.
`
`An objective of the present invention is therefore to solve
`the above problems with the prior art and provide a flat light
`source that implements a uniform and very bright light that
`is limited to a predetermined angular range, and that has no
`variations in luminance due to position within the light
`surface, without increasing the power consumption, amount
`of heat generated, or the size of the entire apparatus.
`DISCLOSURE OF THE INVENTION
`
`The present invention achieves the above objective by
`providing a flat light source that uses a light-diffusing sheet
`
`LGE_001128
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`LGE_001128
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`
`
`5,944,405
`
`3
`formed of a transparent material containing no particles of a
`light-diffusing agent. The front surface of this light-diffusing
`sheet has minute irregularities formed at random;
`these
`minute irregularities have a surface roughness of at least the
`wavelength of the light from the light source, but no more
`than 100 gm; and, when a cumulative frequency distribution
`curve of the heights of the minute irregularities is plotted,
`with the percentage of the cumulative frequency distribution
`of the heights of these irregularities along the Y-axis and the
`heights of the minute irregularities along the X-axis,
`the
`cumulative frequency distribution curve has a convex por-
`tion oriented towards a lower side of coordinates and the
`
`average value of the heights of the minute irregularities is
`greater than a median value thereof.
`A light source is disposed along at least one side edge
`surface of this light-diffusing sheet, and the light-diffusing
`sheet can be provided superimposed on a light-emitting
`surface of an optically conductive member that is a flat
`optically transmissive plate, or an optically conductive
`member that has a rectangular cavity therein, where the
`optically conductive member has a light-reflecting layer on
`the rear surface thereof.
`
`The light-diffusing sheet may also be provided in such a
`manner as to cover a window in a lamp housing. This lamp
`housing is configured to contain a light source,
`light-
`reflecting wall surfaces of the lamp housing cover the rear
`and side surfaces of the light source, and the window is
`formed in the front surface of the light source.
`When the above described optically conductive member
`is formed of a fiat, optically transmissive plate, the front
`surface of the optically conductive member may be a fiat
`surface having a surface roughness less than the wavelength
`of the light of the light source.
`A sheet that is a one-dimensional or two-dimensional
`
`array of convex or concave lenses may be superimposed
`over the light-diffusing sheet. Similarly, another, identical
`light-diffusing sheet may be superimposed over the first
`light-diffusing sheet.
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`FIG. 1 is a perspective view of an example of a trans-
`missive type of display device using an edge-lit type of flat
`light source in accordance with this invention;
`FIG. 2 is a perspective view of an example of a trans-
`missive type of display device using a back-lit type of flat
`light source in accordance with this invention;
`FIG. 3 is a cross-sectional illustrative view through an
`example of an edge-lit flat light source, showing groups of
`projections formed on both surfaces of the light-diffusing
`sheet;
`FIG. 4 is a perspective view of an example of a lens sheet
`used by the present invention;
`FIG. 5 is a perspective view of another example of a lens
`sheet used by the present invention;
`FIG. 6 is a perspective view of a further example of a lens
`sheet used by the present invention;
`FIG. 7 is a perspective view of yet another example of a
`lens sheet used by the present invention;
`FIG. 8 is a perspective view of an example of two
`superimposed lens sheets used by the present invention;
`FIG. 9 is a sectional view showing the paths of light rays
`travelling from the interior of the optically conductive plate
`to the outside thereof;
`FIG. 10 is a sectional view showing light rays that have
`been emitted by the tunnel effect from the optically conduc-
`tive plate as they proceed into the lens sheet;
`
`10
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`15
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`20
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`25
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`4
`FIG. 11 is a sectional view showing how some of the light
`rays proceeding towards the exterior of the optically con-
`ductive plate are totally reflected while others are
`transmitted, when the light-diffusing sheet of the present
`invention is used;
`FIG. 12 shows an example of the method of fabricating
`the light-diffusing sheet of the present invention;
`FIG. 13 is a perspective view of an example of the
`light-diffusing sheet of the present invention, fabricated by
`the fabrication method shown in FIG. 12;
`FIG. 14 is a cross-sectional view through an edge-lit flat
`light source of the prior art, showing the lack of a lens sheet;
`FIG. 15 is a perspective view of the edge-lit fiat light
`source of the prior art, showing a lens sheet having a flat rear
`surface;
`FIG. 16 is a sectional view of the configuration of FIG.
`15;
`FIG. 17 is a graph of cumulative frequency distribution
`f(R), with surface roughness (that
`is,
`the percentage of
`cumulative frequency distribution of depths R of concavities
`in the mold) plotted along the X-axis and with surface
`roughness (that is, the depths R of the concavities in the
`mold) plotted along the Y-axis, in a fabrication mold for
`imprinting projections of the light-diffusing sheet in accor-
`dance with the present invention;
`FIG. 18 is a sectional view of a fabrication mold having
`the characteristic of the cumulative frequency distribution
`curve fA(R) in FIG. 17;
`FIG. 19 is a is a sectional view of a fabrication mold
`
`having the characteristic of the cumulative frequency dis-
`tribution curve fB(R) in FIG. 17;
`FIG. 20 is a sectional view illustrating undercutting
`formed by aggregations of minute spherical particles of the
`metal chrome, during the matte-plating of chrome onto the
`indented surface of the roll mold used for fabrication;
`FIG. 21 shows a graph relating to the heights of projec-
`tions of the light-diffusing sheet used in this invention (that
`is, the surface roughness of the light-diffusing sheet) and the
`distribution thereof as a cumulative frequency distribution
`curve f(R), with surface roughness (that is, the percentage of
`cumulative frequency distribution of heights R of the peaks)
`plotted along the X-axis and surface roughness (that is, the
`heights R of the peaks) along the Y-axis, in a case in which
`the cumulative frequency distribution curve has a downward
`convexity and a relationship (average valueémedian value)
`is satisfied;
`FIG. 22 is a fragmentary expanded three-dimensional
`visualization of measurements showing the projections of a
`light-diffusing sheet used in this invention having the cumu-
`lative frequency distribution characteristics of FIG. 21;
`FIG. 23 shows a graph relating to the heights of projec-
`tions of the light-diffusing sheet used in this invention (that
`is, the surface roughness of the light-diffusing sheet) and the
`distribution thereof as a cumulative frequency distribution
`curve f(R), with surface roughness (that is, the percentage of
`cumulative frequency distribution of heights R of the peaks)
`plotted along the X-axis and surface roughness (that is, the
`heights R of the peaks) plotted along the Y-axis, in a case in
`which the cumulative frequency distribution curve has a
`downward convexity and a
`relationship (average
`valueémedian value) is satisfied;
`FIG. 24 is a partial expanded three-dimensional visual-
`ization of measurements showing the projections of a light-
`diffusing sheet used in this invention having the cumulative
`frequency distribution characteristics of FIG. 23;
`
`LGE_001129
`
`LGE_001129
`
`
`
`5,944,405
`
`5
`FIG. 25 is a graph showing the heights of projections of
`the light-diffusing sheet used in this invention (that is, the
`surface roughness of the light-diffusing sheet) and the dis-
`tribution thereof as a cumulative frequency distribution
`curve f(R), with surface roughness (that is, the percentage of
`cumulative frequency distribution of heights R of the peaks)
`plotted along the X-axis and surface roughness (that is, the
`heights R of the peaks) plotted along the Y-axis, in a case in
`which the average value of R has a maximum at 52% and the
`cumulative frequency distribution curve has a downwardly
`convex portion and an upwardly convex portion;
`FIG. 26 is a partial expanded three-dimensional visual-
`ization of measurements showing the projections of a light-
`diffusing sheet used in this invention having the cumulative
`frequency distribution characteristics of FIG. 25;
`FIG. 27 is a graph showing the heights of projections of
`the light-diffusing sheet used in this invention (that is, the
`surface roughness of the light-diffusing sheet) and the dis-
`tribution thereof as a cumulative frequency distribution
`curve f(R), with surface roughness (that is, the percentage of
`cumulative frequency distribution of heights R of the peaks)
`plotted along the X-axis and surface roughness (that is, the
`heights R of the peaks) plotted along the Y-axis, in a case in
`which the cumulative frequency distribution curve is linear;
`FIG. 28 is a partial enlarged perspective view of projec-
`tions of a light-diffusing sheet formed of ridges of a rect-
`angular equilateral triangular sectional shape and having the
`cumulative frequency distribution curve of FIG. 27;
`FIG. 29 is a graph showing the heights of projections of
`the light-diffusing sheet used in this invention (that is, the
`surface roughness of the light-diffusing sheet) and the dis-
`tribution thereof as a cumulative frequency distribution
`curve f(R), with surface roughness (that is, the percentage of
`cumulative frequency distribution of heights R of the peaks)
`plotted along the X-axis and surface roughness (that is, the
`heights R of the peaks) plotted along the Y-axis, in a case in
`which the cumulative frequency distribution curve has a
`partial upwardly convex portion and a partial downwardly
`convex portion, and the average value is less than the
`median value.
`
`FIG. 30 is a partial expanded three-dimensional visual-
`ization of measurements showing the projections of a light-
`diffusing sheet used in this invention having the cumulative
`frequency distribution characteristics of FIG. 29;
`FIG. 31 is a graph showing the heights of projections of
`the light-diffusing sheet used in this invention (that is, the
`surface roughness of the light-diffusing sheet) and the dis-
`tribution thereof as a cumulative frequency distribution
`curve f(R), with surface roughness (that is, the percentage of
`cumulative frequency distribution of heights R of the peaks)
`plotted along the X-axis and surface roughness (that is, the
`heights R of the peaks) plotted along the Y-axis, in a case in
`which the cumulative frequency distribution curve has a
`downward convexity over the entire region thereof;
`FIG. 32 is a partial expanded three-dimensional visual-
`ization of measurements showing the projections of a light-
`diffusing sheet used in this invention having the cumulative
`frequency distribution characteristics of FIG. 32;
`FIG. 33 shows the angular distribution of luminance of a
`light-emitting surface of a fiat light source (Example 1 and
`Comparative Example 1); and
`FIG. 34 shows the angular distribution of luminance of a
`light-emitting surface of another fiat light source (Example
`8) of this invention.
`BEST MODES FOR CARRYING OUT THE
`INVENTION
`
`Embodiments of a flat light source in accordance with the
`present invention and a display device using this flat light
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`10
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`20
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`source will be described below with reference to the accom-
`
`panying drawings.
`An edge-lit type of fiat light source is shown in FIG. 1. In
`this figure, reference numeral 1 denotes an optically con-
`ductive plate, where this optically conductive plate 1 is
`configured of a solid optically transmissive fiat plate. A light
`source such as a linear light source 3 is provided along one
`edge surface of this optically conductive plate 1. A reflective
`mirror 5 is provided behind the light source 3. Light emitted
`from the light source 3 enters the interior of the optically
`conductive plate 1 either directly or after being reflected by
`the reflective mirror (also a lamp housing with reflective
`surfaces) 5. It is reflected internally as shown for example in
`FIG. 3 or it
`is emitted directly outside from within the
`optically conductive plate 1. A light reflecting layer 2 is
`provided on the rear surface of the optically conductive plate
`1. The surface of the optically conductive plate 1 opposite to
`the light reflecting layer 2 forms a light-emitting surface. A
`light-diffusing sheet 8 is provided facing this light-emitting
`surface, and light emitted through the light-emitting surface
`passes through the light-diffusing sheet 8. Light that has
`passed through the light-diffusing sheet 8 passes through a
`lens sheet 4 and then reaches a transmission type display
`device 6. A gap 9 is formed between the light-diffusing sheet
`8 and the optically conductive plate 1, and between the
`light-diffusing sheet 8 and the lens sheet 4. Projections 41
`that will be described in more detail later are formed on the
`
`surfaces of the light-diffusing sheet 8 facing these gaps 9.
`Instead of being solid, the optically conductive plate 1
`could have an empty structure. In such a case, the light-
`emitting surface of the solid optically conductive plate 1 and
`the surface thereof in contact with the light reflecting layer
`2 would each be in the form of a flat plate, with the space
`therebetween forming a rectangular cavity.
`With a back-lit light source as shown in FIG. 2, the light
`source 3 is a linear or point light source and accommodated
`within a lamp housing 5. The lamp housing 5 extends over
`the rear and sides of the light source 3 and acts as reflective
`surfaces for reflecting the light from the light source 3 in the
`direction of the light-diffusing sheet 8.
`In FIGS. 1 and 2, reference number 100 denotes a flat
`light source in its entirety and reference number 200 denotes
`a display device in its entirety.
`In accordance with this present invention, projections 41
`are obtained by forming minute irregularities at random
`(such as in a sharkskin pattern or a pear skin pattern) over
`the entire surface of the light-diffusing sheet 8. These minute
`irregularities have a surface roughness that is at least the
`wavelength of the light emitted from the light source but is
`no more than 100 gm. When the percentages of the cumu-
`lative frequency distribution of the heights of the minute
`irregularities are plotted along the Y-axis and the heights of
`these minute irregularities along the X-axis, the cumulative
`frequency distribution curve should typically have a convex
`portion oriented towards the lower side of the coordinates
`and the average value of the height of the minute irregu-
`larities should be greater than the median thereof.
`The light-diffusing sheet 8 used by the present invention
`is formed from a transparent material. In this case,
`the
`transparent material may be a (meth)acrylic ester such as
`polymethyl (meth)acrylate or polyethyl (meth)acrylate
`[where “(meth)acrylate” means either methacrylate or acry-
`late throughout the specification] or a copolymer thereof; a
`polyester such as polyethylene terephthalate or polybutylene
`terephthalate; a thermoplastic resin such as a polycarbonate,
`polystyrene or polymethylpentene resin; an ultraviolet light-
`
`LGE_001130
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`LGE_001130
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`
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`5,944,405
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`7
`or electron beam-curable, transparent resin which has been
`crosslinked and cured by ultraviolet rays or electron beams;
`a transparent glass; or a transparent ceramic material.
`As ultraviolet light curable resins or electron beam cur-
`able resins, compositions comprising a prepolymer, oligo-
`mer and/or monomer having, in its molecule, a polymeriz-
`able unsaturated bond such as a (meth)acryloyl group or a
`(meth)acryloyloxy group or an epoxy group.
`In this
`connection,
`the term “(meth)acryloyl” is used to mean
`“acryloyl” or “methacryloyl” throughout the specification.
`Such prepolymer and oligomer include an acrylate such as
`urethane (meth)acrylate, polyester (meth)acrylate epoxy
`(meth)acrylate, and an unsaturated polyester. Further, a
`dipentaerythritol penta (meth)acrylate can be exemplified as
`the monomer used in this case.
`
`It is important that these materials contain absolutely no
`light-diffusing particles, unlike in the ordinary light-
`diffusing plate (such as that cited in U.S. Pat. No. 4,729,067)
`For a light-diffusing sheet 8 for an edge-lit fiat
`light
`source, a sheet of the above described transparent material
`that has a thickness on the order of 5 to 200 pm is used.
`Alternatively,
`for a back-lit
`light source,
`the light-
`diffusing sheet 8 must support its own weight and bear
`external forces, so it should have a thickness on the order of
`1 to 10 mm to prevent distortion.
`The light-diffusing sheet 8 could have a single-layer
`structure as shown in FIG. 1, or a double-layer structure as
`shown in FIG. 13, or even a multi-layer structure with three
`or more layers.
`The projections 41 on the surface of the light-diffusing
`sheet 8 are formed as fine irregularities of a height that is at
`least the wavelength of the light from the light source, but
`no more than 100 gm. These irregularities could be formed
`directly by subjecting the surface of the optically transmis-
`sive material to embossing by a thermal press or to sand-
`blasting, or they could be formed by a method such as
`casting. Alternatively, a layer of an optically transmissive
`material having these projections 41 could be formed on the
`flat surface of the optically transmissive plate. More
`specifically, a method such as that described in Japanese
`Patent Laid Open No. 5-169,015 and U.S. Pat. No. 4,576,
`850 could be used, in which projections 41 are formed on the
`surface of an optically transmissive base film 12 by using
`rolls and the above ultraviolet- or electron-beam-curable
`
`(hardenable) plastic.
`transmitted thereto
`In addition to diffusing the light
`isotropically,
`the projections 41 formed on the light-
`diffusing sheet 8 are designed to create the gap 9 of at least
`the wavelength 7» of the light
`from the light source
`(dimension Ax) between the light-diffusing sheet 8 and a
`smooth surface 10 that is the outer surface of the optically
`conductive plate 1 and/or between the light-diffusing sheet
`8 and a smooth surface 7 that is the rear surface of the lens
`sheet 4, as shown in FIG. 3, at least over small areas of the
`light-diffusing sheet 8. As will be described later, if the
`dimension AX of each gap is less than that of the wavelength
`of the light from the light source, it will not be possible for
`the smooth surface 10 of the optically conductive plate 1 to
`refiect all the light sufficiently. Conversely, if the height of
`the irregularities that form the projections 41 exceeds 100
`gm,
`the irregularities of the projections 41 will become
`visible to the eye. This is not desirable.
`If the above design conditions are satisfied, the projec-
`tions 41 can be of any irregular shape. However, the most
`preferable form thereof, from the viewpoints of obtaining a
`uniform angular distribution of luminance within a certain
`
`8
`angle of diffusion and a uniform luminance distribution
`within the surface of the light source, is such that minute
`irregularities are formed randomly (such as in a sharkskin
`pattern or a pear skin pattern) over the entire surface of the
`light-diffusing sheet 8, and these minute irregularities have
`a surface roughness that is at least the wavelength of the
`light emitted from the light source but is no more than 100
`gm. When a curve of the cumulative frequency distribution
`of the heights of these minute irregularities is plotted as
`shown in FIG. 31, with the percentage of the cumulative
`frequency distribution of the heights of the minute irregu-
`larities along the Y-axis and the heights of these minute
`irregularities along the X-axis,
`the cumulative frequency
`distribution curve should typically have a convex portion
`oriented towards the lower side of the coordinates and the
`
`average value of the height of the minute irregularities
`should be greater than the median thereof.
`With the configuration as described above, the projections
`41 act as a light-diffusing layer so that light rays such as L1
`and L2 incident on the rear surface of the light-diffusing
`sheet 8, as shown in FIG. 3, are diffused isotropically
`thereby. Thus the incident
`light has a uniform angular
`distribution and a high-quality, very bright flat light source
`that does not have an obvious dot pattern is obtained.
`It is preferable that the shapes of the projections 41 are
`such that concavities therebetween become narrower
`towards the bottom, as shown in FIGS. 22 and 24 or more
`schematically in FIGS. 18 and 19. The cross-sectional shape
`of the projections 41 are curves such as sine waves or
`cycloids in which the periodic amplitude thereof varies at
`random in each cycle, or such as sectional curves that are
`formed at random by a method such as sand-blasting or
`milling and which have narrowed bottoms. The depths
`thereof and the distances between neighboring peaks are at
`least the wavelength of the light from the light source, but
`no more than 100 gm, and minute concavities and convexi-
`ties are molded therein in such a manner that the above
`
`cumulative frequency distribution condition is satisfied.
`Such a configuration is preferable from the viewpoints of a
`uniform angular distribution of the transmitted light, the
`height of the transmissivity, and, as will be described later,
`the total refiectivity at the boundary between the surface of
`the optically conductive plate and the light-diffusing sheet.
`If this configuration is used with a fabrication method in
`which the sheet is cast in a metal mold, cured, and then
`removed, such as that described in Japanese Patent Laid
`Open No. 5-169,015, a defective product will be produced.
`In other words, if the central portions of the concavities
`expand, it will become impossible, or at least very difficult,
`to remove the casting from the mold.
`The light-diffusing sheet 8 could be formed by various
`different methods, such as a known casting method, a
`thermal pressing method (as is described in Japanese Patent
`Laid Open No. 6-157,310); or a method of using a roll-
`embossing plate to emboss a thermoplastic plastic film that
`can be cured by ultraviolet light, then illuminating the film
`with ultraviolet light