CN206224061U - A kind of bore hole 3D display device and bore hole 3D gratings - Google Patents

Abstract

The utility model discloses a kind of bore hole 3D display device and bore hole 3D gratings.Wherein, the bore hole 3D gratings include substrate and are arranged on the micro-lens arrays layer of the substrate surface, and the micro-lens arrays layer includes the lenticule unit of multiple prism-shapeds, and the top of the lenticule unit is sphere.By using multiple lenticule unit composition micro-lens arrays layers arranged in arrays, because the top of lenticule unit is sphere, there are 360 degree of light splitting to act on for it, can separate the image through specific arrangement on focal plane is regular, thus observer can around display device 360 degree watch bore hole 3D rendering.

Description

A kind of bore hole 3D display device and bore hole 3D gratings

Technical field

The utility model is related to display technology field, more particularly to a kind of bore hole 3D display device and bore hole 3D gratings.

Background technology

Enter the epoch in Qinghua high with digital audio/video, bore hole 3D technology is ready to appear, and at present, bore hole 3D exists Some electronic products covering major domain spread out, the bore hole 3D products for having listed mainly have bore hole 3D mobile phones, bore hole 3D TVs, Bore hole 3D notebooks, bore hole 3D video cameras etc., bore hole 3D stereo display techniques are the newest, forefront high-new of image industry It is tired out that technology, its appearance and development change the vision that conventional planar image gives people, and is also of image making field Technological revolution, is a change for matter, has wide prospect in future.

Simply, 3D imagings are exactly on special high-definition liquid crystal display base, accurately to paste the special 3D optics group of last layer Part (optical glass+lenticular high molecular polymer is constituted), and using its natural light splitting effect, 3D will be crossed by specially treated Video information, it is regular to separate, so as in certain viewing areas, realize bore hole 3D effect.The column of traditional design is saturating Mirror grating or slit grating are upper in only the horizontal direction to be presented radian, has optically focused to act in the horizontal direction, and image is also only in level Direction shoots arrangement, therefore can only be in watching bore hole 3D rendering in horizontal direction.

The bore hole image formed by traditional lenticular sheet and slit grating can only before display screen level side To 3D rendering is watched in certain limit, not enough, business application attraction is little for visual impact.Although current holographic technique 360 degree of energy sees the image of bore hole 3D, but holographic technique is too high to equipment and technical requirements, expensive, realizes difficult, it is impossible to It is widely used.

Thus prior art could be improved and improve.

Utility model content

In view of above-mentioned the deficiencies in the prior art part, the purpose of this utility model is to provide a kind of bore hole 3D display device With bore hole 3D gratings, can 360 degree watch bore hole 3D rendering.

In order to achieve the above object, the utility model takes following technical scheme：

A kind of bore hole 3D gratings, including substrate and the micro-lens arrays layer of the substrate surface is arranged on, it is described micro- Lens array layer includes the lenticule unit of multiple prism-shapeds, and the top of the lenticule unit is sphere.

In described bore hole 3D gratings, the lenticule unit includes quadrangular portion and is arranged on the quadrangular portion top Sphere portion.

In described bore hole 3D gratings, each lenticule unit covers m × m pixel, and the m is one in 4-12 whole Number.

In described bore hole 3D gratings, the cross section in the quadrangular portion is square.

In described bore hole 3D gratings, the radius of curvature R of the sphere of the lenticule unit meets equation below：

Wherein, d is the thickness of the substrate, k₁It is empirical coefficient, n₁It is the refractive index of the substrate, n₂It is lenticule battle array The refractive index of row layer.

In described bore hole 3D gratings, the thickness of the substrate d meets equation below：

Wherein, P is the length or width of the pixel of display screen, and S is the default sighting distance of display screen, and W is binocular vision away from a is display Shield the thickness of upper strata glass substrate.

In described bore hole 3D gratings, the length of side of the lenticule unit is 1-2mm.

In described bore hole 3D gratings, the radius of curvature of the lenticule unit is 1-4mm.

In described bore hole 3D gratings, the level interval and vertical interval of each lenticule unit are 1.239mm, curvature Radius is 2.13248mm.

A kind of bore hole 3D display device, including bore hole 3D gratings as described above.

Compared to prior art, the utility model provides a kind of bore hole 3D display device and bore hole 3D gratings.Wherein, it is described Bore hole 3D gratings include substrate and are arranged on the micro-lens arrays layer of the substrate surface, and the micro-lens arrays layer includes many The lenticule unit of individual prism-shaped, the top of the lenticule unit is sphere.It is in matrix by using multiple lenticule units Micro-lens arrays layer is rearranged, because the top of lenticule unit is sphere, there are 360 degree of light splitting to act on for it, can be by focal plane On the image through specific arrangement it is regular separate, therefore observer can around display device 360 degree watch bore hole 3D Image.

Brief description of the drawings

The stereogram of the bore hole 3D gratings that Fig. 1 is provided for the utility model.

The front view of the bore hole 3D gratings that Fig. 2 is provided for the utility model.

The top view of the bore hole 3D gratings that Fig. 3 is provided for the utility model.

In the bore hole 3D gratings that Fig. 4 is provided for the utility model, the front view of lenticule unit.

In the bore hole 3D gratings that Fig. 5 is provided for the utility model, 3D image-forming principle schematic diagrames.

In the bore hole 3D gratings that Fig. 6 is provided for the utility model, the pixel region that human eye light source point is covered with lenticule unit The triangle schematic diagram that domain is formed.

Specific embodiment

The utility model provides a kind of bore hole 3D display device and bore hole 3D gratings.To make the purpose of this utility model, skill Art scheme and effect are clearer, clear and definite, and the embodiment that develops simultaneously referring to the drawings is further described to the utility model.Should Work as understanding, specific embodiment described herein is only used to explain the utility model, be not used to limit the utility model.

The bore hole 3D display device that the utility model is provided, it includes display screen and the bore hole being attached on the display screen 3D gratings.When being moved before display screen, because the loop cycle of viewpoint occurs, image occurs jump, to make image smooth eyes, Jump is not obvious, it is necessary to many using viewpoint, but viewpoint is excessive when can so cause display again, and image resolution ratio is low, therefore selects as follows The high-resolution display screens of 4K2K, specifically, the display screen is liquid crystal panel, the resolution ratio of the liquid crystal panel for 3840 × 2160。

Refer to Fig. 1, Fig. 2 and Fig. 3, the bore hole 3D gratings, including substrate 20 and be arranged on the upper table of the substrate 20 The micro-lens arrays layer in face, the micro-lens arrays layer includes the lenticule unit 10 of multiple prism-shapeds, i.e. multiple lenticule lists Unit 10 arranges to form micro-lens arrays layer in dot matrix；The top of the lenticule unit 10 is sphere.

Because the top of lenticule unit is sphere, there is 360 degree of scopes of sphere light splitting to act on, can by focal plane through spy The image of different arrangement is regular to be separated, thus observer can around display device 360 degree watch bore hole 3D rendering.

Fig. 4 is referred to, the lenticule unit 10 includes quadrangular portion 120 and is arranged on the top of the quadrangular portion 120 Sphere portion 110.The cross section in the quadrangular portion 120 is rectangle, i.e., the bottom of described lenticule unit 10 is rectangle.Change and Yan Zhi, four sides of the lenticule unit 10 are plane.The length-width ratio of rectangle is identical with display screen pixel；Such as This is set, and is conducive to the laminating between lenticule unit 10.Because the pixel of display screen is generally square, therefore the present embodiment In, the cross section in the quadrangular portion 120 is square.

Further, each lenticule unit 10 covers m × m pixel, and the m is an integer in 4-12.I.e. m takes Value can be any one integer in 4,5,6,7,8,9,10,11,12, depending on screen resolution and pixel size.This reality Preferably m is 8 in applying example.Because display screen is generally rectangular, and then the micro-lens arrays layer is rectangle.

Also referring to Fig. 5, the thickness of the substrate d meets equation below：

Wherein, P is the length or width (pixel length and width are equal in the present embodiment) of the pixel of display screen, and S is default for display screen Sighting distance, W be binocular vision away from (spacing of i.e. two), a is the thickness of display screen upper strata glass substrate.Preferably, described presetting regards Away from the optimum viewing distance for display screen.The substrate 20 is preferably glass substrate, and in the present embodiment, the substrate 20 is that electron level is saturating Bright glass.

In the present embodiment, the resolution ratio of display screen is 3840 × 2160, and the optimum viewing distance S of display screen is 1400mm, screen image Plain size is 0.15525 × 0.15525mm, i.e. P=0.15525mm.W takes 65mm, n₁Take 1.5, a and take 0.5mm.

From the similar triangle theory of Fig. 5, P：W=h：S.H=3.343846mm can be tried to achieve.Computing formula herein Consider the refractive index of substrate, therefore the thickness of h not substrates, the thickness d that calculate substrate also needs to be converted.Consider There is one layer of glass substrate above liquid crystal panel pixel, from the formula of refractive index, d=h × n₁-a.In addition, liquid crystal surface There are polaroid, glue etc. between plate upper strata glass substrate and substrate, estimate that its thickness is 0.5mm.Therefore in the present embodiment, substrate 20 thickness d=3.343846 × 1.5-0.5-0.5=4.0157693mm.

According to the thickness d of the substrate, grating focal length f=d × k is calculated₁, k₁It is empirical coefficient.The empirical coefficient k₁For 1.1.Then grating focal length f=4.0157693 × 1.1=5.5173459mm.

According to grating focal length f, the radius of curvature of lenticule unit is calculatedIn other words, institute The radius of curvature R for stating the sphere of lenticule unit meets equation below：

Wherein, n₂It is the refractive index of micro-lens arrays layer, 1.56 is taken in the present embodiment.

The computing formula of the radius of curvature R is drawn by the general principle of first-order theory.In the present embodiment, R= 5.5173459/ [1.5/ (1.56-1)]=2.059809mm.

The size (length and width) of thickness d and lenticule unit according to the substrate, calculates lenticule cellular array spacingIn the present embodiment, lenticule unit covering 8 × 8 pixels, i.e. lenticule unit Width is m × P=8 × 0.15525mm.

Fig. 6, vertex of a triangle behaviour eye source point are referred to, base is the pixel region of lenticule unit covering.By Similar triangle theory understands that S/ (S+d1)=X/ (m × P), d1 herein does not consider the refractive index of glass, due to lenticule list The focal length of unit need to be focused in pixel, then from refractive index formula, d1=(f-a)/n1.Thus the battle array of lenticule unit is obtained Column pitch X=8 × 0.15525 × (1400/ (1400+5/1.5))=1.239mm.

To sum up, optimum viewing distance uses 1400mm, when design thickness of glass substrate is 4mm；The then curvature of lenticule unit half Footpath R is：2.13248mm, the level interval and vertical interval of each lenticule unit are 1.239mm.

Certainly, it is contemplated that the optimum viewing distance of different product is different, the span of the radius of curvature of the lenticule unit Can be 1-4mm.The length of side of the lenticule unit can be 1-2mm.

Grating Film (micro-lens arrays layer) is made according to above-mentioned grating parameter, this Grating Film is attached to the thick electron levels of 4mm On clear glass, i.e. the micro-lens arrays layer is attached on electron level clear glass.Again by this glass and display screen Opencell glass is close to, display process 360 degree arrangement multi-cams shooting images by specific arrangement, after arrangement Pattern matrix screen is displayed on the focal plane for reproducing microlens array rear, according to light path principle, by special by rule The light focusing reduction that the image of different arrangement casts out various image primitives through the lenticule of grating array, so that again Existing microlens array front reconstructs the 3-D view of object space scene, because image is after being shot through 360 degree of cameras of arrangement Synthesis, and grating lens unit is circle, therefore can be around 360 degree of viewings of TV during viewing.

It is understood that for those of ordinary skills, can according to the technical solution of the utility model and The design of its utility model is subject to equivalent or change, and all these changes or replacement should all belong to appended by the utility model Scope of the claims.

Claims (10)

1. a kind of bore hole 3D gratings, it is characterised in that including substrate and be arranged on the micro-lens arrays layer of the substrate surface, The micro-lens arrays layer includes the lenticule unit of multiple prism-shapeds, and the top of the lenticule unit is sphere.

2. bore hole 3D gratings according to claim 1, it is characterised in that the lenticule unit includes quadrangular portion and sets Put the sphere portion at the top of the quadrangular portion.

3. bore hole 3D gratings according to claim 1, it is characterised in that each lenticule unit covers m × m pixel, The m is an integer in 4-12.

4. bore hole 3D gratings according to claim 2, it is characterised in that the cross section in the quadrangular portion is square.

5. bore hole 3D gratings according to claim 4, it is characterised in that the radius of curvature of the sphere of the lenticule unit R meets equation below：

$R=\frac{(d\×k_1)\×(n_2-1)}{n_1};$

Wherein, d is the thickness of the substrate, k₁It is empirical coefficient, n₁It is the refractive index of the substrate, n₂It is micro-lens arrays layer Refractive index.

6. bore hole 3D gratings according to claim 5, it is characterised in that the thickness of the substrate d meets equation below：

$d=\frac{P\×S}{W}\×n_1-a;$

Wherein, P is the length or width of the pixel of display screen, and S is the default sighting distance of display screen, and W is binocular vision away from a is on display screen The thickness of layer glass substrate.

7. bore hole 3D gratings according to claim 4, it is characterised in that the length of side of the lenticule unit is 1-2mm.

8. bore hole 3D gratings according to claim 1, it is characterised in that the radius of curvature of the lenticule unit is 1- 4mm。

9. bore hole 3D gratings according to claim 1, it is characterised in that the level interval of each lenticule unit and vertical Spacing is 1.239mm, and radius of curvature is 2.13248mm.

10. a kind of bore hole 3D display device, it is characterised in that including the bore hole 3D gratings described in claim 1-9 any one.