CN204166206U - A kind of two-way bore hole stereoscopic display device - Google Patents
A kind of two-way bore hole stereoscopic display device Download PDFInfo
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- CN204166206U CN204166206U CN201420606120.1U CN201420606120U CN204166206U CN 204166206 U CN204166206 U CN 204166206U CN 201420606120 U CN201420606120 U CN 201420606120U CN 204166206 U CN204166206 U CN 204166206U
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Abstract
The utility model discloses a kind of two-way bore hole stereoscopic display device, comprise backlight, 2D display module and 3D light-splitting device, 2D display module is arranged between backlight and 3D light-splitting device, 2D display module is LCD or OLED, it is characterized in that, 2D display module each pixel comprise R, G, B tri-sub pixel, R, G, B tri-sub pixel distribution in diagonal line in pixel.The utility model has the following advantages compared to existing technology: by such structural design, and matching design making light-splitting device can reach and realize according to the needs of display direction the function that both direction anyhow all can realize the bore hole 3D display of same resolution.
Description
Technical field
The utility model relates to 3D field of stereoscopic display, in particular a kind of two-way bore hole stereoscopic display device.
Background technology
The finding world of reduction is more realistically the target that people pursue always.Along with the innovation of display technique, be shown to stereo display from black and white to color, from cathode-ray tube (CRT) to flat pannel display, from SD to high definition, from plane, the visual experience of people becomes truer gradually.Stereo display particularly bore hole stereo technology has become the new development trend in display field.
The principle that realizes of naked-eye stereoscopic display is at common TFT-LCD (Thin Film Transistor-LCD, hereinafter referred to as LCD) PDP, light-splitting device is added before the panels such as LED, binocular parallax will be had (when left eye and right eye watch the actual object of certain distance, the visual pattern received is slightly different) plane picture project respectively in right and left eyes, merge finally by brain and to form stereoscopic vision.Slit grating is a kind of device typically realizing bore hole 3D light splitting, it realizes the principle of bore hole 3D display as shown in Figure 1, by 2D display panel (as LCD) is preposition (also can be rearmounted, be preposition shown in figure) slit grating, chequered with black and white striped is formed by blocking at slit grating, make left eye can only see the image that left eye is corresponding, right eye can only see the image that right eye is corresponding, watches the image with certain parallax simultaneously and produce 3D stereo display effect due to right and left eyes.
Problems existing when more than illustrating that slit grating principle of work is to better illustrate that existing LCD realizes bore hole 3D below.Below stress existing issue.As described above, LCD collocation slit grating can realize naked eye 3 D function.By the classification of arrangement of subpixels direction, LCD has two kinds of specifications usually, is called horizontal screen and perpendicular screen.Be respectively a kind of common horizontal screen and perpendicular screen LCD schematic diagram as shown in Figure 2 and Figure 3.
A kind of common method realizing bore hole 3D for add one deck slit grating before LCD.The cycle of this layer of grating will carry out mating blocking with pixel period, realizes three-dimensional light splitting function.The mode of blocking sub-pixel can be adopted to realize light splitting for existing horizontal screen LCD grating, such as, block two row sub-pixels, as a screen periods.And when horizontal screen LCD half-twist use, the direction due to sub-pixel also have rotated 90 °, and grating just cannot adopt the mode of blocking sub-pixel to realize three-dimensional light splitting.The mode of occluded pixels can only be adopted to realize three-dimensional light splitting.3D resolution will be caused like this to reduce.Concrete as shown in Figure 4 and Figure 5, Fig. 4 and Fig. 5 be respectively horizontal screen LCD laterally and vertical (be that horizontal dextrorotation turn 90 degrees in figure, be certainly rotated counterclockwise 90 degree also can) when using two kinds of situations, contrast 3D slit grating shielding mode.According to the angle on grating and LCD limit, can be divided into and vertically to block and two kinds of modes are blocked in inclination, what draw in legend is the mode of vertically blocking, and when tilting to block, principle roughly the same.3D grating shielding mode when Fig. 4 is horizontal screen LCD transverse direction use, when horizontal screen LCD laterally uses, 3D grating shielding mode mainly contains 2 kinds of selections, block sub-pixel mode and occluded pixels mode, the difference of watching the design of viewpoint number according to 3D can block again each sub-pixel of 2-n or pixel (wherein n be generally 2-9 do not limit be integer), but when n gets identical value, the cycle of blocking sub-pixel mode grating is obviously little than the cycle of occluded pixels mode grating.Shielding mode in figure is to block 2 row sub-pixels.In figure, Ph is the cycle of slit grating, Ph=2SubPixels in this example, i.e. 2 times of sub pixel width; Bh is slit grating open region width, is generally the slit grating cycle Ph of 30%-50%.Fig. 5 is vertical (the namely horizontal dextrorotation turn 90 degrees) service condition of horizontal screen LCD, and in figure, Pv is the cycle of slit grating, Pv=2Pixels in this example, i.e. 2 times of pixel wide; Bv is slit grating open region width, is generally the slit grating cycle Pv of 30%-50%.3D grating cannot be adopted to block sub-pixel mode realize 3D light splitting occluded pixels mode therefore can only be adopted to realize 3D light splitting because horizontal screen LCD vertically uses.The difference of watching the design of viewpoint number according to 3D can block again each sub-pixel of 2-n or pixel (wherein n be generally 2-9 do not limit be integer).Due to when n gets identical value, the cycle of blocking sub-pixel mode grating is obviously little than the cycle of occluded pixels mode grating, because pixel wide is generally 3 times of sub pixel width, therefore Pv=3Ph, namely in this example, horizontal screen LCD when vertically using the slit grating cycle be 3 times of slit grating cycle when laterally using.Because screen periods and 3D resolution are inversely proportional to, so just cause when viewpoint number n is the same, resolution when horizontal screen LCD vertically uses reduces to laterally use 1/3.With should viewpoint number n the same time, also 3D resolution can be reduced to original 1/3 when perpendicular screen LCD laterally uses.In order to address this problem, the utility model proposes a kind of bore hole stereoscopic display device, the effect that two-way 3D display resolution is anyhow consistent can be reached.
Utility model content
The purpose of this utility model is to overcome the deficiencies in the prior art, provides a kind of two-way bore hole stereoscopic display device.
The utility model is achieved through the following technical solutions:
A kind of two-way bore hole stereoscopic display device, comprise backlight, 2D display module and 3D light-splitting device, 2D display module is arranged between backlight and 3D light-splitting device, 2D display module is LCD or OLED, it is characterized in that, each pixel of 2D display module comprises R, G, B tri-sub pixel, R, G, B tri-sub pixel distribution in diagonal line in pixel.
As improvement, pixel is divided into nine grids shape, the size of each grid is identical, R, G, B tri-sub pixel be distributed in respectively in three grid that same diagonal line passes.
As improvement, residue is not filled black matrix by R, G, B tri-in the blank grid that occupies of sub pixel.
As improvement, replace part or all of black matrix by white pixel.
As improvement, R, G, B sub-pixel has corresponding TFT switch, and each R, G, B sub-pixel has corresponding TFT switch-linear hybrid in the blank grid be adjacent.
As improvement, residue is not filled black matrix by R, G, B tri-in the blank grid that occupies of sub pixel and corresponding TFT switch thereof.
As improvement, the grid that each non-sub-pixel of nine grids occupies is divided into some sublattices, arranges R, G, B sub-pixel, TFT switch, black matrix or white pixel in sublattice.
As improvement, 3D light-splitting device is slit grating, slit grating sets gradually lower glass substrate from top to bottom, infrabasal plate COM electrode, infrabasal plate SEG electrode, liquid crystal layer, upper substrate SEG electrode, upper substrate COM electrode, top glass substrate, there is insulation course to separate between infrabasal plate COM electrode and infrabasal plate SEG electrode, between upper substrate SEG electrode and upper substrate COM electrode, have insulation course (SiO
2deng) separate, infrabasal plate COM electrode and upper substrate COM electrode are whole ITO electrode, infrabasal plate SEG electrode is strip electrode parallel to each other, strip electrode and the x-axis of infrabasal plate SEG electrode form θ angle, 0 °≤θ≤90 °, upper substrate SEG electrode is strip electrode parallel to each other, and strip electrode and the y-axis of upper substrate SEG electrode form θ ' angle, 0 °≤θ '≤90 °.
As improvement, insulation course is SiO
2material is made.
The driving method of above-mentioned two-way bore hole stereoscopic display device is, when laterally using, the voltage be applied on liquid crystal slit grating upper substrate COM electrode is 0V, and the voltage be applied on infrabasal plate SEG electrode is V1, and infrabasal plate COM electrode and upper substrate SEG electrode are all set to 0V voltage; During vertical use, being applied to liquid crystal slit grating infrabasal plate COM electrode voltage is 0V, and the voltage be applied on upper substrate SEG electrode is V1, and upper substrate COM electrode and infrabasal plate SEG electrode are all set to 0V voltage, V1>0.
As improvement, the voltage be applied on infrabasal plate SEG electrode is the square-wave voltage of +/-V1, polarizes to prevent liquid crystal material
The utility model has the following advantages compared to existing technology: by the structure coordinating above type of drive like this He the utility model proposes, can realize not needing to re-design light-splitting device, both the needs according to display direction can have been reached, realize both direction anyhow all can show by same resolution bore hole 3D in fact, in order to realize anyhow can showing bore hole 3D, if adopt common light-splitting device, anyhow need to design respectively in two kinds of situations, if this dynamic switchable light-splitting device designed in employing the present invention, then do not need again to make light-splitting device and can realize both direction display bore hole 3D anyhow, technology can realize two reverse display bore hole 3D anyhow, just the bore hole 3D resolution in one of them direction will lower than another one direction, the present invention can realize the same resolution of both direction.
Accompanying drawing explanation
Fig. 1 slit grating 3D displaying principle figure.
The horizontal screen that Fig. 2 is common and perpendicular screen LCD schematic diagram.
The horizontal screen LCD transverse direction that Fig. 3 is common and vertical use grating shielding mode schematic diagram.
Fig. 4 the utility model one-piece construction schematic diagram.
Figure 52 D display module 200 cross-sectional view.
Figure 62 D display module Pixel Design.
Figure 72 D display module pixel TFT placement location designs.
Other embodiments of Fig. 8 the utility model Pixel Design.
Fig. 9 horizontal screen LCD of the present utility model when both direction uses anyhow 3D grating block schematic diagram.
Figure 103 D light-splitting device cross-sectional view.
Figure 113 D light-splitting device each layer electrode structure schematic diagram.
Liquid crystal slit grating each layer electrode drive voltage corresponding relation schematic diagram when Figure 12 laterally shows.
Liquid crystal slit grating each layer electrode drive voltage corresponding relation schematic diagram when Figure 13 vertically shows.
The horizontal screen LCD schematic diagram that Fig. 2 is common.
The perpendicular screen LCD schematic diagram that Fig. 3 is common.
The horizontal screen LCD laterally use grating shielding mode schematic diagram that Fig. 4 is common.
The common horizontal screen LCD of Fig. 5 vertically uses grating shielding mode schematic diagram.
Fig. 6 the utility model one-piece construction schematic diagram.
Figure 72 D display module 200 cross-sectional view.
Fig. 8 is the Pixel Design of 2D display module in prior art.
Fig. 9 is the Pixel Design of 2D display module in the utility model.
Figure 10 is 2D display module pixel TFT placement location design in prior art.
Figure 11 is 2D display module pixel TFT placement location design in the utility model.
Other embodiments one of Figure 12 the utility model Pixel Design.
Other embodiments two of Figure 13 the utility model Pixel Design.
When Figure 14 horizontal screen LCD of the present utility model laterally uses, 3D grating blocks schematic diagram.
When Figure 15 horizontal screen LCD of the present utility model vertically uses, 3D grating blocks schematic diagram.
Figure 163 D light-splitting device cross-sectional view.
Figure 173 D light-splitting device infrabasal plate SEG electrode structure schematic diagram.
Figure 183 D light-splitting device upper substrate SEG electrode structure schematic diagram.
Figure 193 D light-splitting device infrabasal plate COM electrode structure schematic diagram.
Figure 20 3D light-splitting device upper substrate COM electrode structure schematic diagram.
Liquid crystal slit grating infrabasal plate COM electrode drive voltage corresponding relation schematic diagram when Figure 21 laterally shows.
Liquid crystal slit grating upper substrate COM electrode drive voltage corresponding relation schematic diagram when Figure 22 laterally shows.
Liquid crystal slit grating infrabasal plate SEG electrode drive voltage corresponding relation schematic diagram when Figure 23 laterally shows.
Liquid crystal slit grating upper substrate SEG electrode drive voltage corresponding relation schematic diagram when Figure 24 laterally shows.
Liquid crystal slit grating infrabasal plate COM electrode drive voltage corresponding relation schematic diagram when Figure 25 vertically shows.
Liquid crystal slit grating upper substrate COM electrode drive voltage corresponding relation schematic diagram when Figure 26 vertically shows.
Liquid crystal slit grating infrabasal plate SEG electrode drive voltage corresponding relation schematic diagram when Figure 27 vertically shows.
Liquid crystal slit grating upper substrate SEG electrode drive voltage corresponding relation schematic diagram when Figure 28 vertically shows.
Embodiment
Below embodiment of the present utility model is elaborated; the present embodiment is implemented under premised on technical solutions of the utility model; give detailed embodiment and concrete operating process, but protection domain of the present utility model is not limited to following embodiment.
As shown in Figure 6, be one-piece construction sectional view of the present utility model.300 represent backlight, and 200 is 2D display modules, and 100 is light-splitting devices.200 represent 2D display module, can be LCD, OLED module etc.This 2D display module 200 concrete structure is shown in Fig. 7, and (the utility model is for LCD, OLED overall architecture different but, but dot structure is similar, the utility model is mainly for dot structure), wherein 201 are TFT glass substrates, 202 is TFT (Thin Film Transistor thin film transistor (TFT)) layers, 203 is liquid crystal layers, and 204 is CF (the color film of Color Filter) layers, and 205 is CF glass substrates.This light-splitting device can be slit grating, column mirror grating, liquid crystal slit grating, liquid crystal lens etc.
As shown in Figure 8, Figure 9, Fig. 8 is prior art Pixel Design Fig. 9 is Pixel Design of the present utility model, the dot structure of the utility model 2D display module is different from the strip rgb pixel arrangement of prior art, Pixel Design is that RGB is by diagonal row by the utility model.This is one of key technical feature of the present utility model.As shown in Figure 7, the position of TFT driving switch can be placed in color blocking overlay area as prior art, also can be placed in not by color blocking overlay area.
What Figure 10 showed is prior art pixel TFT placement location, and Figure 11 is the utility model pixel TFT placement location.In figure, TFT-R, TFT-G, TFT-B are respectively R, G, G sub-pixel TFT switch placement location.BM (Black Matrix) is black matrix, and effect is the metal wire blocking region and pixel interior transmission data and the switching signal not having color blocking.Only can placement location example with regard to TFT in figure, be not limited to position shown in figure.The position of prior art TFT driving switch can be placed in color blocking overlay area, and TFT driving switch position of the present utility model can be placed in color blocking overlay area, also can be placed in not by color blocking overlay area.This is also one of key technical feature of the present utility model.Doing the benefit brought like this is to improve the pixel aperture ratio in color blocking district.Usually for the small sizes such as mobile phone (such as 3.5 inches to 6.5 inches), if higher (as being greater than 300PPI) pixel aperture ratio usually all less (being such as less than 30%) for PPI (Pixels per inch per inch pixel count).Although only there is about 1/3 size of prior art in the utility model color blocking district, by the placement location of TFT being arranged on the aperture opening ratio that can to ensure at least 33% outside color blocking district, aperture opening ratio is even better than the prior art pixel design in high PPI situation.
Pixel Design thought of the present utility model can also for some embodiments.Be another kind of pixel layout as shown in figure 12, by non-for part color blocking overlay area, can be originally that the region of BM changes white pixel into.The position of TFT can be placed on outside color blocking district equally.The benefit done like this to improve display frame brightness.Certainly other Pixel Design embodiments based on the utility model thought are also had, be another pixel layout as shown in figure 13, whole pixel is divided into 9 parts, and the program arranges except the idea of RGB sub-pixel except reservation the utility model by diagonal line, is also divided by other 1/9 pixel regions again.Concrete dividing mode has a variety of, and the example enumerated in legend is that other 1/9 pixel regions each are divided into 2 parts, is set to 2 kinds of colors respectively, and these 2 kinds of colors are followed the example of as centered by this 1/9 region, its X-direction and sub-pixel colors corresponding to Y-direction.Final result is the R that the row or column at each sub-pixel place has 4/6, the G of 1/6, the B of 1/6, or the B of 4/6, the G of 1/6, the R of 1/6, or the G of 4/6, the R of 1/6, the B of 1/6.The benefit done like this is because RGB ratio is identical, can increase the brightness of white picture.But the shortcoming brought also is obviously, the quantity of each exactly pixel lining pixel is raised to 15, and namely TFT number is 15, and TFT equally must be placed in color blocking district to prior art, and aperture opening ratio has decline.The write of data-signal and pixel driver also will become more complicated.Be only for this example and illustrate that pixel design of the present utility model has a variety of possibility.
Introduce principle of work of the present utility model and beneficial effect thereof below.
Figure 14 and the occlusion effect schematic diagram blocking the horizontal screen LCD of employing the utility model Pixel Design that Figure 15 shows that using slit grating as 3D light-splitting device.
According to the angle on grating and LCD limit, can be divided into and vertically to block and two kinds of modes are blocked in inclination, what draw in Fig. 9 is the mode of vertically blocking, and when tilting to block, principle roughly the same.3D grating shielding mode when Figure 14 is horizontal screen LCD transverse direction use, when horizontal screen LCD laterally uses, 3D grating shielding mode mainly contains 2 kinds of selections, block sub-pixel mode and occluded pixels mode, the difference of watching the design of viewpoint number according to 3D can block again each sub-pixel of 2-n or pixel (wherein n be generally 2-9 do not limit be integer), but when n gets identical value, the cycle of blocking sub-pixel mode grating is obviously little than the cycle of occluded pixels mode grating.Shielding mode in figure is to block 2 row sub-pixels.In figure, Ph is the cycle of slit grating, Ph=2SubPixels in this example, i.e. 2 times of sub pixel width; Bh is slit grating open region width, is generally the slit grating cycle Ph of 30%-50%.Figure 15 is vertical (the namely horizontal dextrorotation turn 90 degrees) service condition of horizontal screen LCD, and in figure, Pv is the cycle of slit grating, Pv=2Pixels in this example, i.e. 2 times of pixel wide; Bv is slit grating open region width, is generally the slit grating cycle Pv of 30%-50%.3D grating can be adopted equally to block sub-pixel mode when vertically using owing to adopting the horizontal screen LCD of the utility model dot structure and realize 3D light splitting, therefore due to when n gets identical value, Pv=Ph, namely in this example, when horizontal screen LCD vertically uses, the slit grating cycle is equal with slit grating cycle when laterally using.Namely 3D resolution is also identical.Therefore the dot structure that the utility model proposes can reach the beneficial effect that two-way 3D display resolution is anyhow consistent.
Although the above-mentioned basic thought of the utility model solves the problem that two-way 3D display resolution is inconsistent anyhow, but need when applying light-splitting device to redesign and again fit and make to change the direction of light-splitting device with adaptive display direction, still not convenient in actual use.In order to further head it off, the utility model also proposed a kind of light-splitting device, and arranging in pairs or groups to play together with dot structure of the present utility model does not need to re-design light-splitting device and both can reach and realize both direction anyhow according to the dynamic changeable light-splitting device of the needs of display direction and all can realize bore hole 3D and show.The light-splitting device that the utility model proposes can adopt liquid crystal slit grating technology or liquid crystal lens technology is this kind of can based on the technology of automatically controlled switching.First illustrate using liquid crystal slit grating as embodiment.The principle of liquid crystal lens is similar.
As shown in figure 16,3D light-splitting device (for liquid crystal slit grating) 100, lower glass substrate 101, infrabasal plate COM electrode 102, infrabasal plate SEG electrode 103, has insulation course (SiO between electrode 102 and electrode 103
2deng) separate, liquid crystal layer 104, upper substrate SEG electrode 105, upper substrate COM electrode 106, there is insulation course (SiO between electrode 105 and electrode 106
2deng) separate, top glass substrate.In figure, liquid crystal slit grating infrabasal plate COM electrode 102 and upper substrate COM electrode 106 are whole ITO electrode, infrabasal plate SEG electrode 103, are strip electrode parallel to each other, in the horizontal direction in (x-axis), are spaced apart Pd between each strip electrode.For reducing the moire fringes that stereo display is formed, strip electrode and y-axis can form θ angle, 0 °≤θ≤90 °.Upper substrate SEG electrode 105 is strip electrode parallel to each other, in the vertical direction in (y-axis), is spaced apart Pd between each strip electrode.For reducing the moire fringes that stereo display is formed, strip electrode and x-axis can form θ angle, 0 °≤θ≤90 °.Infrabasal plate SEG electrode 103 and upper substrate SEG electrode 105, its grating fringe cycle and angle can design as required respectively.Grating electrode material can be the transparent conductive materials such as ITO, IZO.Each grating electrode periphery adds circuit lead, in order to form peripheral circuit.Metal material such as copper, fine aluminium etc. can be adopted to make for reducing impedance peripheral circuit.
Following citing illustrates driving method.First the driving method of liquid crystal slit grating 100 is described.Divide and laterally use and vertical use two kinds of patterns.
When laterally using, if the voltage that a certain moment is applied on liquid crystal slit grating upper substrate COM electrode 106 is 0v, and the square wave that the voltage be applied on infrabasal plate SEG electrode is +/-V1 polarizes to prevent liquid crystal material, the size of voltage V1 and square wave frequency/cycle etc. determine according to characteristics such as liquid crystal materials.Other two-layer electrodes and infrabasal plate COM electrode 102 and upper substrate SEG electrode 105, due to inoperative, are all set to COM voltage and 0V.Owing to defining certain voltage difference between upper substrate COM electrode 106 region and infrabasal plate SEG signal electrode 103, form chequered with black and white striped (fringe spacing and angle are determined by the design parameter of common electrode 103), according to the 3D displaying principle of Fig. 1,3D display namely can be formed within region.
During vertical use, if the voltage that a certain moment is applied on liquid crystal slit grating infrabasal plate COM electrode 102 is 0v, and the square wave that the voltage be applied on upper substrate SEG electrode 105 is +/-V1 polarizes to prevent liquid crystal material, the size of voltage V1 and square wave frequency/cycle etc. determine according to characteristics such as liquid crystal materials.Other two-layer electrodes and upper substrate COM electrode 106 and infrabasal plate SEG electrode 103, due to inoperative, are all set to COM voltage and 0V.Owing to defining certain voltage difference between infrabasal plate COM electrode 102 region and upper substrate SEG signal electrode 105, form chequered with black and white striped (fringe spacing and angle are determined by the design parameter of common electrode 103), according to the 3D displaying principle of Fig. 1,3D display namely can be formed within region.
The above type of drive of such cooperation and the dot structure that the utility model proposes, can realize not needing re-designing light-splitting device and both can reach and realize both direction anyhow according to the dynamic changeable light-splitting device of the needs of display direction and all can realize bore hole 3D display.The type of drive of 3D light-splitting device 100 (liquid crystal slit grating) mode that the utility model proposes is suitable for and liquid crystal lens device equally, and when difference is to use liquid crystal lens device, electrode number is more and can independently control.
The foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all do within spirit of the present utility model and principle any amendment, equivalent to replace and improvement etc., all should be included within protection domain of the present utility model.
Claims (9)
1. a two-way bore hole stereoscopic display device, comprise backlight, 2D display module and 3D light-splitting device, described 2D display module is arranged between described backlight and described 3D light-splitting device, described 2D display module is LCD or OLED, it is characterized in that, described 2D display module each pixel comprise R, G, B tri-sub pixel, described R, G, B tri-sub pixel distribution in diagonal line in pixel.
2. a kind of two-way bore hole stereoscopic display device as claimed in claim 1, it is characterized in that, pixel is divided into nine grids shape, the size of each grid is identical, described R, G, B tri-sub pixel be distributed in respectively in three grid that same diagonal line passes.
3. a kind of two-way bore hole stereoscopic display device as claimed in claim 2, is characterized in that, residue is not filled black matrix by described R, G, B tri-in the blank grid that occupies of sub pixel.
4. a kind of two-way bore hole stereoscopic display device as claimed in claim 3, is characterized in that, replaces part or all of described black matrix by white pixel.
5. a kind of two-way bore hole stereoscopic display device as claimed in claim 2, it is characterized in that, described R, G, B sub-pixel has corresponding TFT switch, and described each R, G, B sub-pixel has corresponding TFT switch-linear hybrid in the blank grid be adjacent.
6. a kind of two-way bore hole stereoscopic display device as claimed in claim 5, is characterized in that, residue is not filled black matrix by described R, G, B tri-in the blank grid that occupies of sub pixel and corresponding TFT switch thereof.
7. a kind of two-way bore hole stereoscopic display device as claimed in claim 2, it is characterized in that, the grid that each non-sub-pixel of described nine grids occupies is divided into some sublattices, arranges R, G, B sub-pixel, TFT switch, black matrix or white pixel in described sublattice.
8. a kind of two-way bore hole stereoscopic display device as claimed in claim 1, it is characterized in that, described 3D light-splitting device is slit grating, described slit grating sets gradually lower glass substrate from top to bottom, infrabasal plate COM electrode, infrabasal plate SEG electrode, liquid crystal layer, upper substrate SEG electrode, upper substrate COM electrode, top glass substrate, insulation course is had to separate between described infrabasal plate COM electrode and described infrabasal plate SEG electrode, insulation course is had to separate between described upper substrate SEG electrode and described upper substrate COM electrode, described infrabasal plate COM electrode and described upper substrate COM electrode are whole ITO electrode, described infrabasal plate SEG electrode is strip electrode parallel to each other, strip electrode and the x-axis of described infrabasal plate SEG electrode form θ angle, 0 °≤θ≤90 °, described upper substrate SEG electrode is strip electrode parallel to each other, strip electrode and the y-axis of described upper substrate SEG electrode form θ ' angle, 0 °≤θ '≤90 °.
9. a kind of two-way bore hole stereoscopic display device as claimed in claim 8, it is characterized in that, described insulation course is SiO
2material is made.
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104238131A (en) * | 2014-10-20 | 2014-12-24 | 中航华东光电(上海)有限公司 | Bidirectional naked eye three-dimensional display device and driving method thereof |
| CN104950462A (en) * | 2015-07-21 | 2015-09-30 | 京东方科技集团股份有限公司 | 3D display device and working method thereof |
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2014
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104238131A (en) * | 2014-10-20 | 2014-12-24 | 中航华东光电(上海)有限公司 | Bidirectional naked eye three-dimensional display device and driving method thereof |
| CN104950462A (en) * | 2015-07-21 | 2015-09-30 | 京东方科技集团股份有限公司 | 3D display device and working method thereof |
| US10187632B2 (en) | 2015-07-21 | 2019-01-22 | Boe Technology Group Co., Ltd. | 3D display device and driving method thereof |
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