Patent Document

BACKGROUND OF THE INVENTION 
     This invention concerns the autostereoscopic display which can especially observe the stereoscopic vision by the naked eye for the autostereoscopic display. 
     The lenticular method, the parallax barrier method, the integral photography method, and the holography method, etc are known as a method of displaying the stereoscopic vision which can be observed by the naked eye.  FIG. 14(   a ) is an outline chart where the entire past autostereoscopic display is shown, and  FIG. 14(   b ) and  FIG. 14(   c ) are outline especially charts where they explain the integral photography method. 
     Lens sheet  101  where the convex lens is arranged like the array is set up in front of display  106  as shown in  FIG. 14 . It explains the integral photography method which is one of the methods of displaying the stereoscopic vision which can be observed by the naked eye by using these figures. In  FIG. 14(   b ), a three dimensional position is shown, and one section in that is  FIG. 14(   c ). 
     When the pixel on display  106  is very small compared with the lens, and the pixels at the position of white circle  1502  shown in  FIG. 14(   b ) ( c ) are displayed on display  106  with a certain color and brightness, light from the pixels gathers in the position of white circle  1502  by the effect of lens sheet  101 , and it becomes a ray which spreads from that point. 
     When observer  1501  observes this field of view  1503  shown in  FIG. 14(   c ), it comes to be able to perceive a point light, namely an object exists in the white circle  1502 . It is also possible to use the pinhole instead of this lens. 
     Moreover, the lenticular method that achieves the stereoscopic effect only in horizontal direction by using binocular parallax exist, too, in the way the lenticular lens sheet with half cylinder shaped lenticular lens is set up in front of display  106  instead of the convex lens, and the slender images for the right eye and the left eye which are alternately arranged along the longitudinal direction of the lenticular lens are displayed in display  106 . In these methods, the image displayed on display  106  is generated with image generation device  1504  for the binocular vision shown in  FIG. 14(   a ). 
     PC which generates computer graphics, multi eye camera, and single eye type cameras combined with lens sheet, etc. are enumerated as image generation device  1504  for the binocular vision. 
     The technology concerning the lenticular method is indicated in a past technology. 
     The technology, which makes the non-luminescence area (black matrix) between pixels unremarkable by devising the arrangement of the pixel on the display, is indicated in JP3101521B (hereafter, patent document 1). 
     The technology, which makes the black matrix between pixels unremarkable by expanding each pixel with the lens, is indicated in JP2540999B (hereafter, patent document 2). 
     The technology, which makes the black matrix between pixels unremarkable by installing diffusion board  102  between display  106  and lenticular lens sheet  101  as shown in  FIG. 15 , is indicated in JP2777241B (hereafter, patent document 3). 
     The technology, which avoids unnatural binocular vision caused when the light which penetrates a pixel passes through the lenticular lens that is not correctly associated with the pixel by inserting the shading film between each lenticular lenses of the lenticular lens sheet, and the street in the lenticular lens which is not the lenticular lens that light, which penetrates the pixel, is correctly associated with the pixel, is indicated in JP289320B (hereafter, patent document 4). 
     SUMMARY OF THE INVENTION 
     The technology, which had been described to patent document 1, changed the arrangement of the pixel on the display, and it had the problem that the cost of execution rose because it was not able to use a general purpose display. 
     The technology, which had been described to patent document 2, had the problem that the cost of execution rose, because a lot of numbers of lenses which expanded the pixel were necessary. 
     The technology, which had been described to patent document 3, had the problem that the reproduced stereoscopic vision blotted by the color of each pixel mixing with the color of the next pixel. 
     There were problems in the technology of the description to patent document 4. First problem is that black matrix between pixels stands out by being expanded with lens. Second problem is that assumed color cannot be shown to the observer by the Red and the Green and the Blue each display part&#39;s of each subpixel being expanded, and causing the color separation. 
     The assumed color cannot be shown to the observer by The Red and the Green and the Blue each display part&#39;s of each subpixel being expanded, and causing the color separation. 
       FIG. 16  is an outline chart where the part of the display of the image of a past auto stereoscopic display is shown. The image display part is an installation of diffusion board  102  between lens sheet  101  and display  106  in this figure. 
     The purpose to use diffusion board  102  is, before the ray reaches lens seat  101 , for instance, to avoid the color separation, by mixing three primary colors that red subpixel  107 Ra, green subpixel  107 Ga, and blue subpixel  107 Ba of pixel  107   a.    
     However, there is a problem that it mixes by three primary colors of the adjoining pixel such as Blue subpixel  107 Ba of pixel  107   a  and red subpixel  107 Rb of pixel  107   b , and the color of the reproduced stereoscopic vision blots in a past technology. Therefore, the composition, in which the mixture of three primary colors of the adjoining pixel is canceled, is needed. 
     Then, the purpose of this invention is to offer the autostereoscopic display where the phenomenon that a black matrix and the color separation stand out with the lens is not caused and the phenomenon that the reproduction stereoscopic image blots by the mixture of the color of the pixel is not caused so far according to an easy composition. 
     In this invention, in the past autostereoscopic display shown in  FIGS. 15 and 16 , it was assumed the composition in which the trench along the black matrix between pixels was put on the diffusion board  102  disposed between display  106  and lens sheet  101 . 
     Moreover, it was assumed the composition in which the angle of trench achieves the total reflection of incident light of each pixel from inside of diffusion board  102  to the oblique side of the trench. In addition, it was assumed the composition in which the angle of trench achieves the total reflection of incident light of each pixel from inside of diffusion board  102  to the oblique side of the trench. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is an outline chart of the image display part in the autostereoscopic display of the embodiment  1  of the invention. 
         FIG. 2  is a plan where it explains the pixel on the display and the arrangement of pixel and black matrix. 
         FIG. 3  is an outline chart where it explains the ray which passes in the diffusion board. 
         FIG. 4  is a simplified cross-sectional view taken along section line &lt;X-X′&gt; of  FIG. 2  where it explains the angle and the length of the trench. 
         FIG. 5  is an outline chart where it explains the viewing angle on the display. 
         FIG. 6  is a simplified cross-sectional view taken along section line &lt;Y-Y′&gt; of  FIG. 2  where it explains the angle and the length of the trench. 
         FIG. 7  is a simplified drawing where the configuration of the trench of the diffusion board is shown. 
         FIG. 8  is an outline chart of the image display part in the autostereoscopic display in a modified embodiment 1 of the embodiment 1. 
         FIG. 9  is an outline chart of the image display part in the autostereoscopic display device in a modified embodiment 2 of the embodiment 1. 
         FIG. 10  is an outline chart of the image display part in the autostereoscopic display device in a modified embodiment 3 of the embodiment 1. 
         FIG. 11  is an outline chart of the image display part in the autostereoscopic display in a modified embodiment 4 of the embodiment 1. 
         FIG. 12  is an outline chart of the image display part in the autostereoscopic display in the embodiment 2 of the invention. 
         FIG. 13  is an outline chart of the image display part in the autostereoscopic display in the embodiment 3. 
         FIG. 14  is an outline chart of a past autostereoscopic display and the image display part. 
         FIG. 15  is an outline chart of a past autostereoscopic display. 
         FIG. 16  is an outline chart of the image display part in a past autostereoscopic display. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Hereafter, it explains the embodiments of this invention with reference to the drawings. 
     Embodiment 1 
     Hereafter, it explains embodiment 1 of executing this invention by using  FIG. 1  to  FIG. 7 . In this embodiment, the width of the trench put from the display side to the diffusion board is the same as the width of a black matrix or example of assumption as the angle of trench achieving the total reflection of the incident light from inside of the diffusion board to the oblique side of the trench is the same. 
     In the embodiment all, the point part of the trench may not be a pointed one, and may have a width, and worn roundness. Moreover, the trench of the embodiments is an isosceles triangle whose center line is perpendicular to the display, passing the center of the black matrix between pixels; however, the requirement need not be strictly met. 
       FIG. 1  is an outline chart where the part of the display of the image of the autostereoscopic display in the embodiment 1 is shown. The above mentioned image display part is an installation of diffusion board  102  between lens sheet  101  and display  106  in  FIG. 1 . 
     Display  106  is the one that two or more pixels such as pixel  107   a ,  107   b , and  107   c  are spread. 
     Pixel  107   a  consists of red subpixel  104 Ra, green subpixel  104 Ga, blue subpixel  104 Ba, and black matrix  105  which is the non-display part between each subpixel. 
     Diffusion board  102  has trench  103  put from a side of display  106  having the same width as the width of black matrix  105  at the position of each black matrix  105  between pixels on the display, and the trench angle of each trench  103  is a total reflection angle for an incident light from the inside of the diffusion board of each pixel to the oblique side of trench  103 . 
       FIG. 2  is a plan view where it explains the pixel on the display and the arrangement of a black matrix used by the embodiments of the invention. Each three primary color display part (subpixel) R, G, and B queue up at equal intervals, and black matrix  105 , which is non-display part, exists between each. 
     Length of the short side of each three primary color display part R, G, and B is assumed to be p 1 , and length of the long side is assumed to be p 2 . The width of black matrix  105  in the direction of the short vicinity of each three primary color display part R, G, and B is assumed to be d 1 , and the width of black matrix  105  in the direction of the vicinity of length is assumed to be d 2 . 
     In the each embodiment, it is assumed p 1 =35.5 μm, p=143 μm, d 1 =28 μm, and d 2 =47.5 μm.  FIG. 1  is a cross section in one point dot-dashed curve X-X′ shown in  FIG. 2 . 
       FIG. 3  is an outline chart where it explains the ray which passes in the diffusion board in the embodiments. Though ray  501 , 502  diffuses in direction  503  of diffusion in diffusion board  102 , the direction of the ray treated in this text is assumed to be a direction of each ray  501 , 502  which passes in the medium without diffusive. In a general diffusion board such as the becoming frosted glass, the direction of each ray  501 , 502  is strong direction of strength of light, and it assumes that it uses such a diffusion board most in the embodiments. 
     It explains the shape of trench  103  in this embodiment in detail by using  FIG. 1 ,  FIG. 4 , and  FIG. 5 .  FIG. 4  is an outline chart where it explains the angle and the length used by the embodiment. 
     In  FIG. 4 , ray  308  emitted with the angle θ from display  106  can be reflected to the oblique side of trench  103  which has angle φ, height h, and d in width. Ray  308  has a reflection angle θi as same as an incident angle θi. Moreover, the thickness of diffusion board  102  is assumed to be H=100 μm, and the refractive index is assumed to be n=1.7 in the example of each embodiment. When the ray starts going out from the object with the refractive index n into the air, the incident angle θi that provides the total reflection of the ray in the boundary of the object and air should be a critical angle θ M  or more given by next formula (1). It becomes θ M ≈36.03° in the embodiments.
 
θ M =arc sin(1/ n )  [Formula 1]
 
       FIG. 5  is an outline chart where it explains the viewing angle on the display used by the embodiments. When the display viewing angle on display  106  to observer  1501  is θDP, ray  401  from display  106  is emitted by angle θo or more to display  106  in this figure. θo is given by next formula (2).
 θo=(180−θ DP )/2  [Formula 2] 
     In the embodiments, it becomes θo=20° assuming display viewing angle θDP=140°. 
     In  FIG. 1 , if trench  103  is put in diffusion board  102  with the angle φ that provides the total reflection of ray  108  emitted with angle θo from display  106 , the total reflection of all of incident lights from display  106  to trench  103  can occur. Such angle φ should fit next formula (3).
 
φ≧2(θ M −θ DP )  [Formula 3]
 
     Moreover, height h of trench  103  with this angle φ is given by next formula (4).
 
 h=d/{ 2 tan(φ/2)}  [Formula 4]
 
     It is φ&gt;32.06°, and when assuming φ=32.1° for instance, it becomes h=48.66 μm in this embodiment because of d=d1=28 μm. 
       FIG. 6  is an outline chart where the part of the display of the image of the autostereoscopic display seen from the side of red display part  104  Ra in this embodiment is shown, and the cross section in one point dot-dashed curve Y-Y′ shown in  FIG. 2 . 
     Angle φ′ of trench  703  for the total reflection of all of incident lights to the oblique side of trench  703  only has to fit “φ′&gt;32.06°” in  FIG. 6  as the embodiment using trench  103 . 
     Because the above mentioned formula are similar, when assuming d′ (width of the trench  703 )=d 2 =47.5 μm, and φ′=32.1°, it becomes h′ (height of the trench  703 )=82.55 μm. 
       FIG. 7  is a simplified drawing where the configuration of the trench of the diffusion board in this embodiment is shown. Due to the total reflection of the light incident from each pixel to the oblique side of the trench, the mixture of the color of the pixel is reduced and the image quality of the reproduction stereoscopic image can be improved. 
     Hereafter, it explains the modified embodiment of the embodiment 1 by using  FIG. 8  to  FIG. 11 . 
     Modified Embodiment 1 of the Embodiment 1 
     In  FIG. 8 , the height of the trench is enlarged, and the modified embodiment 1 of increasing the incident light to the oblique side of the trench is shown. This modified embodiment is an example of explaining the effect when height h of the trench is predetermined. Though only the example of the cross-sectional view along point dot-dashed line X-X′ shown in  FIG. 2  is shown according to this modified embodiment, cross-sectional view along point dot-dashed line Y-Y′ shown in  FIG. 2  as shown in  FIG. 6  is clear. 
       FIG. 8  is a simplified drawing where the part of the display of the image of the autostereoscopic display when the width of the trench of the diffusion board is equal to the width of a black matrix is shown in this modified embodiment 1. It is assumed that the trench has height h=80 μm, and width d=d 1 =28 μm here. When h and d are given, the angle φ of the trench is given by next formula (5).
 φ=2arc tan( d/ 2 h )  [Formula 5] 
     It becomes angle φ=19.85° of trench  903  in  FIG. 8 . At this time, ray  908  emitted from display  106  at angle θo=20° does not only have the reflection at the oblique side of trench  903  but also the refraction penetration. 
     Moreover, angle θ 1  that ray  909  from display  106  has the total reflection at the oblique side of trench  903  should fit next formula (6).
 
θ 1 ≧θ M −φ/2  [Formula 6]
 
     As a result, θ 1 &gt;26.11° can be filled, and all incident ray to the oblique side of trench  903  can be reflected. 
     Modified Embodiment 2 of the Embodiment 1 
       FIG. 9  is an outline chaff of the modified embodiment 2 of the width of the trench of the diffusion board showing the part of the display of the image of the autostereoscopic display when it is smaller than the width of a black matrix. 
     It is assumed that the trench has height h=80 μm and width d=18 μm&lt;d 1  here. 
     In  FIG. 9 , angle θ 1  that provides the total reflection of ray  1009  from display  106  at the oblique side of trench  1003  should fit θ 1 &gt;29.61° because it becomes angle φ=12.84° of trench  1003 . 
     In this modified embodiment, the mixture of the color of the pixel is reduced by enlarging the height of the trench, and increasing an incident ray to the oblique side of the trench, and the image quality of the reproduction stereoscopic image can be improved. 
     Moreover, because the effect of the improvement is achieved even if the width of the trench is reduced more than the width of a black matrix, accuracy, by which the trench is put, need not be strict. 
     Modified Embodiment 3 of the Embodiment 1 
     It explains the modified embodiment 3 by using  FIG. 10 . This modified embodiment enlarges the height of the trench as modified embodiment 1, and increases an incident ray to the oblique side of the trench. The embodiment provides the angle of the trench and an incident ray to have a total reflection angle from the inside of the diffusion board to the oblique side of the trench. 
     This modified embodiment is an example of explaining the effect when height h of the trench and the angle φ of the trench are predetermined. 
       FIG. 10  is an outline chart where the part of the display of the image of the autostereoscopic display in this modified embodiment is shown. Trench  1103   a  has height h=80 μm, angle φ=32.1°, and the total reflection of all incident rays from display  106  through the diffusion board  102  to the slope of the trench  1103   a  occurs. Here, when h and φ are given, width d of the trench is given by next formula (7).
   d= 2  h  tan(φ/2)  [Formula 7] 
     It becomes width d=46.03 μm&gt;d 1  of trench  1103   a  in  FIG. 10 . 
     At this time, because a part of red subpixel  104 Rb and blue subpixel  104 Ba overlaps with trench  1103   a , incident ray  1109  comes out of red subpixel  104 Rb, and incident ray  1107  comes out from blue subpixel  104 Ba through the inside of trench  1103   a  to the oblique side of trench  1103   a . They have an incident reflection and refractive penetration to the oblique side of trench  1103   b  adjacent thereto. 
     In this modified embodiment, by making the height of the trench enlarged, and an incident ray to the oblique side of the trench increased, the angle of the trench providing full reflection of all incident light can be achieved. The mixture of the color of the pixel is reduced, and the image quality of the reproduction stereoscopic image can be improved. 
     Moreover, because the effect of the improvement is achieved even if the width of the trench is enlarged more than the width of a black matrix, accuracy of the trench needs not be strict. 
     Modified Embodiment 4 of the Embodiment 1 
     It explains the modified embodiment 4 by using  FIG. 11 . In the modified embodiment, the height of the trench is enlarged and an incident ray is increased to the oblique side of the trench as the modified embodiment 1. Additionally, not only does total reflection occur, but also the angle of the trench and an incident ray from the inside of the diffusion board to the oblique side of the trench are provided. Also, an incident ray from a part of the display through the trench to an oblique side of the trench may have a refraction penetration and an adjacent trench having an angle can provide a total reflection of the incident ray at the oblique side of the adjacent trench. 
       FIG. 11  is an outline chart where the part of the display of the image of the autostereoscopic display in this modified embodiment 4 is shown. Trench  1203   a  can have h=80 μm in height. Ray  1209  comes from red subpixel  104 Rb at angle θo can be partially reflected to display  106 . A part of ray  1209  having the refraction penetration in the oblique side of trench  1203   a  can have a total reflection at the oblique side of trench  1203   b  next to trench  1203   a . The angle φ of the trench should fit next formula (8).
 arc sin {(1/ n )sin(θ o −φ/2)}+φ≧θ M   [Formula 8] 
     It is φ&gt;34.37°, and when assuming φ=34.38° for instance, it becomes d=49.5 μm&gt;d 1  from formula (8) in this modified embodiment. In this modified embodiment, the height of the trench is enlarged and an incident ray is increased to the oblique side of the trench. In addition, a light comes from the part of the display in the trench and is an incident ray reaching the oblique side of the trench from the inside of the diffusion board. The incident ray can have a total reflection including the part of the ray which has the refraction penetration (Because it goes out of the part of the display in the trench and strength of the light is weak, the ray, which reflects in the oblique side of the trench, is disregarded). The mixture of the color of the pixel is reduced, and the image quality of the reproduction stereoscopic image can be improved. 
     Embodiment 2 
     Hereafter, it explains the embodiment 2 of the invention by using  FIG. 12 . This embodiment is an example of forming to the trench the shading layer where light is absorbed. 
       FIG. 12  is an outline chart where the part of the display of the image of the autostereoscopic display in this embodiment is shown.  FIG. 12(   a ) is an example of filling shading layer  1308   a  to trench  1303   a  of the same type as the modified embodiment 3 of the embodiment. 
     Moreover,  FIG. 12(   b ) is an example of forming shading layer  1308   b  thinly to the inner wall of trench  1303   b  of the same type as the modified embodiment 3. 
     Moreover,  FIG. 12(   c ) is an example of thinly forming shading layer  1308   c  under the inner wall of trench  1303   c  of the same type as the modified embodiment 3. Ray  1302   c  emitted from blue subpixel  104 B in trench  1303   c  is absorbed by shading film  1308   c , and ray  1301   c  emitted from red subpixel  104 R in trench  1303   c  has the refraction penetration. 
     Moreover in  FIG. 12(   d ), the width of trench  1303   d  is smaller than the width of black matrix  105 , and example of filling shading layer  1308   d  to trench  1303   d  whose shape is a rectangle is provided, when the shading layer is formed. Thus, when the reflection layer is formed, the shape of the trench can be freely decided. 
     The shading layer is formed to the trench, the mixture of the color of the pixel is reduced, and the image quality of the reproduction stereoscopic image can be improved in this execution example above. 
     Embodiment 3 
     Hereafter, it explains the embodiment 3 of the invention by using  FIG. 13 . This embodiment is an example of forming the reflection layer where light is reflected to the trench. 
       FIG. 13  is a simplified drawing where the part of the display of the image of the autostereoscopic display in this embodiment is shown.  FIG. 13(   a ) is an example of filling reflection layer  1409   a  to trench  1403   a  of the same type as the modified embodiment 3 above described. 
     Moreover,  FIG. 13(   b ) shows that reflection layer  1409   b  is thinly formed to the inner wall of trench  1403   b  of the same type as modified embodiment 3. It is an example of thinly forming shading layer  1408   b . In addition, an incident ray from inside of diffusion board  102  reflects to the oblique side of trench  1403   b , and the ray in trench  1403   b  is absorbed. 
     Moreover,  FIG. 13(   c ) is an example of thinly forming reflection layer  1409   c  under the inner wall of trench  1403   c  of the same type as modified embodiment 3, and forming shading layer  1408   c  thinly. In addition, ray  1402   c  emitted from blue display part  104 B in trench  1403   c  is absorbed by shading film  1408   c , and ray  1401   c  emitted from red display part  104 R in trench  1403   c  has the refraction penetration. 
     Moreover,  FIG. 13(   d ) is an example that the width of the trench  1403   d  is smaller than the width of black matrix  105 . Also,  FIG. 13(   d ) is an example of filling reflection layer  1308   d  to trench  1403   d  whose shape is a rectangle. Thus, when the reflection layer is formed, the shape of the trench can be freely decided. 
     The reflection layer is formed to the trench, the mixture of the color of the pixel is reduced, and the image quality of the reproduction stereoscopic image can be improved in this embodiment. 
     In setting up the diffusion board which puts the trench along the black matrix between pixels between the display and the lens sheet according to the embodiments, a black matrix and the color separation can be desirably achieved. The blot of the color of the reproduction stereoscopic image by the color of the pixel which is mutually adjacent mixing can be improved. 
     According to this invention above, the phenomenon that a black matrix and the color separation stand out with the lens is not caused because the pixel is separated mutually though three primary colors of each pixel are diffused, moreover, the reproduction stereoscopic image does not cause the phenomenon in which blotting by the mixture of the color of the pixel, and be able to display a &lt;high-resolution&gt; stereoscopic image.

Technology Category: 3