CN203397025U - 3D optical grating integrated with 3D interactive electrode and display device comprising same - Google Patents

Abstract

The utility model provides a 3D optical grating integrated with a 3D interactive electrode and a display device comprising the same, and belongs to the technical field of three-dimensional (3D) image displaying. The 3D optical grating at least comprises a first transparent electrode substrate, a liquid crystal layer, a second transparent electrode substrate, and a first polaroid layer which are arranged sequentially from bottom to top, wherein the first transparent electrode substrate, the liquid crystal layer, and the second transparent electrode substrate are used for forming a liquid crystal box of the 3D optical grating; and the 3D interactive electrode used for realizing a 3D gesture man-machine interaction function is configured and arranged on the surface, opposite to the first polaroid layer, of the second transparent electrode substrate. The display device can realize the compatibility of the 3D optical grating and a 3D gesture man-machine interaction technology, and is simple in structure, small in thickness, and low in cost.

Description

Be integrated with the 3D grating of 3D interaction-electrode and the display device that comprises it

Technical field

The utility model belongs to three-dimensional (3D) image display technology field, relates in particular to a kind of 3D of being integrated with interaction-electrode so that it has the 3D grating of 3D gesture interaction function and the display device of using this 3D grating.

Background technology

Three-dimensional (3D) image display device can be divided into two large classes substantially: glasses type stereoscopic display device and glasses-free type (bore hole) stereoscopic display device (automatic display device of stereoscopic image).Wherein in glasses type stereoscopic display device, used polarising glass, shutter glasses and red blue glasses etc., the existence of glasses can cause beholder feel inconvenient and may cause ophthalmology disease.And glasses-free type stereoscopic display device only just can be appreciated stereo-picture by direct viewing screen, therefore, currently over against glasses-free type stereoscopic display device, further investigate.

The 3 D image display method of glasses-free type stereoscopic display device includes lens method, holographic method and parallax barrier method etc.Wherein lens method and parallax barrier method realize 3D demonstration by 3D grating, wherein in lens method, can use lenticular sheet, in parallax barrier method, can use parallax barrier (also referred to as disparity barrier fence), the application of these two kinds of 3D gratings of lenticular sheet and parallax barrier in 3D shows, respectively there is corresponding technological merit, therefore, in its mutually applicable field, apply respectively.

Notice, lenticular sheet and parallax barrier head can form by liquid crystal cell simultaneously, form respectively liquid crystal lenticular sheet and liquid crystal parallax barrier.Figure 1 shows that the simple structure schematic diagram of the stereoscopic display device of conventional use 3D grating.Stereoscopic display device comprises two dimensional image display module 10 and 3D grating 20, backlightly from two dimensional image display module 10, enters, and enters observer's eyes after 3D grating 20.In 3D grating 20, it can be liquid crystal lenticular sheet and liquid crystal parallax barrier.Wherein, liquid crystal parallax barrier is torsion realization the blocking the light from two dimensional image display module 10 by liquid crystal; Liquid crystal lenticular sheet is utilized the birefringent characteristic of liquid crystal, a kind of method is, in the relevant position that need to form a liquid crystal lens, a plurality of electrodes are set, when these electrodes being added to the liquid crystal of different control voltage Shi，Gai positions, in optical characteristics, form the convergence effect (patented technology that is US5493427 referring to U.S. Patent number) that is similar to entity lens pillar.In Fig. 1 example illustrated, 3D grating 20 comprises lower polaroid 210, lower transparent electrode layer 220, liquid crystal (LC) layer 230, upper transparent electrode layer 240 and the upper polaroid 250 setting gradually from bottom to top.Normally, lower transparent electrode layer 220, upper transparent electrode layer 240 are by ITO(Indium Tin Oxide, indium tin metal oxide) conductive glass layer, (for example on lower transparent electrode layer 220 and upper transparent electrode layer 240, on the surface that is opposite in liquid crystal layer 230, be formed with respectively the ITO electrode of certain pattern, the ITO electrode pattern that is used to form parallax barrier as shown in Figure 1), by controlling Formation of liquid crystals parallax barrier or liquid crystal lenticular sheet to the control of ITO electrode.

Along with the maturation of the 3D grating technology such as lenticular sheet and parallax barrier and such as touch technology and, the development of 3D gesture interaction technology, must consider to use the display screen of this 3D grating and the interactive function between people, also realize man-machine interaction.

In 3D gesture interaction technology, mainly use the 3D gesture human-computer interaction technology based on electric field, its variation by electric field detects, follows the tracks of and distinguish user's hand or the movement of finger in 3 D auto space and realizes man-machine interaction and experience.Particularly, by 3D interaction-electrode being applied to the voltage of a certain frequency, obtain quasi-static electric field, when user's finger or hand enter electric field, due to the electric conductivity of human body itself, the distortion thereupon of this quasi-static electric field, the electric field receiving layer of 3D interaction-electrode can judge the variation of electric field, thereby can point the information such as Huo Shou position, moving direction, gesture by computing machine, further by corresponding calculation process, can realize 3D gesture human-computer interactive control.The application if this 3D gesture human-computer interaction technology combines with 3D display technique, three-dimensional (3D) man-machine interaction that can obtain true nature is experienced.

Chinese Patent Application No. is that 201120233060.X, name are called in the Chinese patent of " a kind of touch three-dimensional stereo display device and display panel thereof ", disclosed how that touch sensible signal electric field receiving layer and 3 d display device is integrated, thereby realize the touch controllable function of 3D display screen.

Yet, in prior art, do not disclose the compatible 3D gesture of the 3D display screen human-computer interaction technology how making based on 3D grating, and 3D shows and the combination of 3D gesture man-machine interaction is thought that its cost is high, is difficult to realize by industry always.

In view of this, be necessary to propose a kind of novel 3D grating.

Utility model content

The purpose of this utility model is, realizes at low cost the compatibility of 3D grating and 3D gesture human-computer interaction technology.

For realizing above object or other objects, the utility model provides following technical scheme.

According to one side of the present utility model, a kind of 3D grating of the 3D of being integrated with interaction-electrode is provided, at least comprise setting gradually from the bottom to top:

The first transparent electrode substrate (310),

Liquid crystal layer (320),

The second transparent electrode substrate (330), and

The first layer of polarizer (390);

Wherein, described the first transparent electrode substrate (310), liquid crystal layer (320), the second transparent electrode substrate (330) are used to form the liquid crystal cell of described 3D grating; At the upper composition of the one side that is opposite in described the first layer of polarizer (334) of described the second transparent electrode substrate (330), be provided for realizing the 3D interaction-electrode (340) of 3D gesture human-computer interaction function.

According to the 3D grating of the utility model one embodiment, wherein, described 3D interaction-electrode comprises electric field transmitted layer (344), insulation course (343) and the electric field receiving layer (341,342) setting gradually from the bottom to top.

Preferably, described electric field receiving layer comprises formation the first electric field receiving layer (341) and the second electric field receiving layer (342) at grade, described the first electric field receiving layer (341) correspondence is arranged on the border area of described the second transparent electrode substrate (330), and the second electric field receiving layer (342) correspondence is arranged on the middle section of described the second transparent electrode substrate (330).

Preferably, the thickness range of described insulation course (343) is 10 to 50nm.

According to the utility model 3D grating of an embodiment also, wherein, at the upper composition simultaneously of one side (334) of described the first layer of polarizer of being opposite in of described the second transparent electrode substrate (330) (390), be provided for forming the third electrode (345) of capacitance touch screen electrode.

Preferably, described third electrode (345) is formed on described insulation course (343) with described electric field receiving layer while composition.

Preferably, described electric field receiving layer comprises that correspondence is arranged on the described first electric field receiving layer (341) of the edge surrounding of described the second transparent electrode substrate (330), and described third electrode (345) correspondence is arranged on the middle section of described the second transparent electrode substrate (330).

According to another aspect of the present utility model, a kind of display device (30) is provided, it comprise two dimensional image display module and the above and any be integrated with the 3D grating of 3D interaction-electrode (340), described 3D grating is placed on described two dimensional image display module (100).

In one embodiment, described two dimensional image display module (100) can be Thin Film Transistor-LCD, and the layer of polarizer in described Thin Film Transistor-LCD is used as the lower layer of polarizer of 3D grating simultaneously.

In another embodiment, described two dimensional image display module (100) can be plasma display or organic light emitting diode display, described 3D grating also comprises the second layer of polarizer being placed under described the first transparent electrode substrate, described the first layer of polarizer is used to form the upper layer of polarizer of described 3D grating, and described the second layer of polarizer is used to form the lower layer of polarizer of described 3D grating.

Technique effect of the present utility model is, by on second transparent electrode substrate of top electrode of liquid crystal cell that is used to form 3D grating, be formed for realizing the 3D interaction-electrode of 3D gesture human-computer interaction function, like this, can realize the compatibility of 3D grating (such as liquid crystal parallax barrier or liquid crystal lenticular sheet) and 3D gesture human-computer interaction technology, use the display device of this 3D grating both to there is bore hole 3D Presentation Function, also there is 3D gesture human-computer interaction function, greatly improve user and experience; And, can only by two-layer transparent electrode substrate, realize, it is simple in structure, thickness is little, transmittance is high, preparation cost is low, is easy to integrate with the assembling of two dimensional image display module.

Accompanying drawing explanation

From following detailed description by reference to the accompanying drawings, will make above and other object of the present utility model and advantage more complete clear, wherein, same or analogous key element adopts identical label to represent.

Fig. 1 is the simple structure schematic diagram of the stereoscopic display device of conventional use 3D grating.

Fig. 2 is according to the cross section structure schematic diagram of the display device of the utility model one embodiment.

Fig. 3 is the structural representation of an embodiment of the 3D interaction-electrode of the 3D grating that uses in display device embodiment illustrated in fig. 2.

Fig. 4 is the A-A cross section structure schematic diagram of the interaction-electrode of 3D shown in Fig. 3.

Fig. 5 is the structural representation of another embodiment of the 3D interaction-electrode of the 3D grating that uses in display device embodiment illustrated in fig. 2.

Fig. 6 is the B-B cross section structure schematic diagram of the interaction-electrode of 3D shown in Fig. 5.

Embodiment

What introduce below is some in a plurality of possibility embodiment of the present utility model, aims to provide basic understanding of the present utility model, is not intended to confirm key of the present utility model or conclusive key element or limits claimed scope.Easily understand, according to the technical solution of the utility model, do not changing under connotation of the present utility model, other implementations that one of ordinary skill in the art can propose mutually to replace, therefore, following embodiment and accompanying drawing are only the exemplary illustrations to the technical solution of the utility model, and should not be considered as of the present utility model all or be considered as the restriction of technical solutions of the utility model or restriction.

In the drawings, for the clear thickness that amplifies Liao Cenghe region, but should not be considered to strictly reflect the proportionate relationship of physical dimension as schematic diagram.

In the drawings, for outstanding main layer of the present utility model, do not comprise some less important layers, such as the OCA(Optically Clear Adhesive for pasting between layers, optical lens gelatin) layer.

In the utility model, display plane with two dimensional image display module is defined as xy plane, z coordinate is perpendicular to xy plane, direction from two dimensional image display module to observer (be generally two dimensional image display module and penetrate light to the direction of observer's eyes) is defined as z coordinate positive dirction, wherein, the orientation term such as upper and lower of mentioning in the utility model is to define with respect to the z coordinate of anticipating shown in accompanying drawing.But they are relative concepts, it can be placed according to the use of display device, and orientation is different, observer's orientation changes and correspondingly changes.

Figure 2 shows that according to the cross section structure schematic diagram of the display device of the utility model one embodiment.In this embodiment, this display device 30 is used the 3D grating that is integrated with 3D interaction-electrode 340, and when this 3D grating is fitted in to two dimensional image display module 100, integral body can form the stereoscopic display device with 3D gesture human-computer interaction function.

Continue to consult Fig. 2,3D grating comprises from the bottom to top an ITO conductive glass layer 310, liquid crystal layer 320, the 2nd ITO conductive glass layer 330 and the layer of polarizer 390 that (i.e. the positive dirction of the z axle in figure) stacks gradually.Wherein, the one ITO conductive glass layer 310 and/or the 2nd ITO conductive glass layer 330 have insulation characterisitic, the one ITO conductive glass layer 310, liquid crystal layer 320, the 2nd ITO conductive glass layer 330 can form the major part (being also liquid crystal cell) of 3D grating, simultaneously, in this embodiment, the upper composition of the one side that is opposite in layer of polarizer 390 of the 2nd ITO conductive glass layer 330 (being face 334) is provided for realizing the 3D interaction-electrode 340 of 3D gesture human-computer interaction function.It should be noted that, between above each layer, may also be provided with other specific function layer, for example, between each layer for bonding transparent glue-line or structure firmware, but this does not form restriction of the present utility model.

Particularly, in the one side that is opposite in liquid crystal layer 320 of an ITO conductive glass layer 310,, on face 312, composition forms ITO electrode 311, and ITO electrode 311 is as the bottom electrode of liquid crystal layer 320.Equally, at the 2nd ITO conductive glass layer 330, be opposite in the one side of liquid crystal layer 320,, on face 332, composition forms ITO electrode 331, and ITO electrode 331 is as the top electrode of liquid crystal layer 320.Specifically arranging etc. between ITO electrode 311, liquid crystal layer 320, ITO electrode 331 understood by those skilled in the art, at this, no longer specifically describes.Should be understood that, those skilled in the art can relative set ITO electrode 311 and/or the shape of ITO electrode 331, make this liquid crystal cell can be used for forming liquid crystal parallax barrier or liquid crystal lenticular sheet, for example, U.S. Patent number is that US5493427, name are called and in the patent of " Three-Dimensional Display Unit With a Variable Lens ", disclose the mode that ITO electrode and corresponding component formed or controlled liquid crystal lenticular sheet that arranges.

The liquid crystal parallax barrier forming in 3D grating of take is example, rectilinearly polarized light (layer of polarizer 390 produces) is vertically injected after liquid crystal layer, its polarization direction can be turned round and turn 90 degrees by liquid crystal, therefore, the liquid crystal cell that the one ITO conductive glass layer 310, liquid crystal layer 320 and the 2nd ITO conductive glass layer 336 form can shading in parallel polarization sheet direction, thereby can show fence.

Further, particularly, on same layer conductive glass layer, in the one side on the 2nd ITO conductive glass layer 330, back on liquid crystal layer 320 (being opposite in the one side of layer of polarizer 390), also be on face 334, composition is formed with 3D interaction-electrode 340, and therefore, the 2nd ITO conductive glass layer 330 is double-face electrode structure.3D interaction-electrode 340 is for launching the potential change that forms quasi-static electric field and receive this electric field, thereby can be for realizing 3D gesture human-computer interaction function.Therefore, this 3D interaction-electrode 340 also can be called the electric field electrode of 3D interbedded formation.

Figure 3 shows that the structural representation of an embodiment of the electric field electrode 3D interaction-electrode of the 3D grating using in display device embodiment illustrated in fig. 2; Figure 4 shows that the A-A cross section structure schematic diagram of the 3D of electric field electrode shown in Fig. 3 interaction-electrode.In conjunction with shown in Fig. 1 to Fig. 3, electric field electrode 3D interaction-electrode 340 comprises electric field transmitted layer 344, insulation course 343 and electric field receiving layer 341 and 342.Electric field transmitted layer 344 composition are formed on the face 334 of the 2nd ITO conductive glass layer 330, and it can be whole continuous electrode; At the voltage signal of electric field transmitted layer 344 upper offset such as a certain frequency, can launch formation quasi-static electric field.Insulation course 343 is for being formed on the thin layer on electric field transmitted layer 344, it is isolated with the electricity of electric field receiving layer 341 and 342 for realizing electric field transmitted layer 344, insulation course 343 is thinner, like this, make it not affect the light transmission of display device, particularly, insulation course 343 thickness ranges are 10 to 50nm, for example 25nm.Insulation course 343 can certainly be selected the transparent insulation material that light transmission is higher, for example SiO ₂.In this embodiment, electric field receiving layer is mainly comprised of two parts, be electric field receiving layer 341 and electric field receiving layer 342, electric field receiving layer is that composition forms on insulation course 343, also be, electric field receiving layer 341 and electric field receiving layer 342 are that composition forms at grade substantially, particularly, as shown in Figure 2, electric field receiving layer 341 is the electrode of four strips, its correspondence is arranged on the border area of the 2nd ITO conductive glass layer 330, electric field receiving layer 342 correspondences are arranged on the middle section of the 2nd ITO conductive glass layer 330, article four, in the region that the electrode 341 of strip surrounds, form electric field receiving layer 342.Electric field transmitted layer 344, electric field receiving layer 341 and 342 can choice for use ITO electrode material.

When pointing or hand enters the top of display device 30, will inevitably change the formed electric field of electric field transmitted layer 344, by electric field receiving layer, receive electric field signal with the potential change of judgement electric field, thereby can further calculate the variations such as finger Huo Shou position, moving direction, gesture.It will be appreciated that, 3D interaction-electrode 340 also needs to be used in conjunction with other interaction controlling portion parts etc. and controls function with the complete 3D of realization gesture interaction, at this, omits the specific descriptions to other components.Further it will be appreciated that, the setting of electric field transmitted layer 344, electric field receiving layer 341 and 342 concrete structures and plane composition pattern, the pattern and the structure that are formed on the 3D interaction-electrode in the 2nd ITO electro-conductive glass aspect 334 are not limited to the pattern shown in Fig. 3 and Fig. 5 and structure, it can, according to specific implementation principle and concrete needs, carry out corresponding specific design.

Continue to consult Fig. 2, layer of polarizer 390 is placed in the top of this 3D grating, and it can be used to form the upper layer of polarizer of parallax barrier.Preferably, for the sensitivity that guarantees to touch, for example, the electric capacity of finger is easily added on self-capacitance, and the thickness of layer of polarizer 390 can be arranged in the scope of 0.1mm to 3mm.

Therefore, when 3D grating is placed on two dimensional image display module 100, formed the stereoscopic display device of embodiment as shown in Figure 2, owing to being integrated with 3D interaction-electrode 340, the simultaneously all right compatible 3D gesture interaction function of this stereoscopic display device, can greatly improve user's 3D man-machine interaction and experience.And, during this 3D grating is put, the 2nd ITO conductive glass layer 330 that is used to form liquid crystal cell is used for preparing formation double-face electrode simultaneously, dexterously ITO electrode 331 and double-face electrode 340 are formed on same ITO conductive glass layer 330 two sides, realized the integrated combination of 3D grating and 3D gesture interaction device, integrated degree is high, simple in structure, thickness is little, preparation cost is low.

Figure 5 shows that the structural representation of another embodiment of the 3D interaction-electrode of the 3D grating using in display device embodiment illustrated in fig. 2; Figure 6 shows that the B-B cross section structure schematic diagram of the interaction-electrode of 3D shown in Fig. 5.Shown in Fig. 1, Fig. 5 and Fig. 6, in this embodiment, the one ITO conductive glass layer 310, liquid crystal layer 320, the formed liquid crystal cell of the 2nd ITO conductive glass layer 330 can be controlled by ITO electrode 311,331 biased electrical signals of ITO electrode, thereby can control liquid crystal cell and whether form liquid crystal parallax barrier or liquid crystal lenticular sheet, and then can realize the switching that 2D shows and 3D shows.For make this display device 30 there is 2D human-computer interaction function when 2D shows simultaneously, than Fig. 3 and embodiment illustrated in fig. 4, its also in the one side that is opposite in layer of polarizer 390 of the 2nd ITO conductive glass layer 330 simultaneously composition be provided for forming the ITO electrode 345 of capacitance touch screen electrode.Referring to Fig. 5 and Fig. 6, in this embodiment, 3D interaction-electrode only comprises that correspondence is arranged on the electric field receiving layer 341 of the 2nd ITO conductive glass layer 330 edge surrounding, reserve like this region that electric field receiving layer 341 surrounds, being used for composition forms ITO electrode 345, therefore, the generally corresponding middle section part that is arranged on the 2nd ITO conductive glass layer 330 of ITO electrode 345.ITO electrode 345 is used to form the electrode layer of capacitance touch screen, the concrete structure of ITO electrode 345 and pattern setting, according to specific implementation principle and concrete needs, carry out corresponding specific design, for example, ITO electrode 345 can be used for forming self-capacitance touch screen, also can be used for forming mutual capacitance touchscreens.The concrete structure setting of ITO electrode 345 is can application reference Ren Wei FocalTech Systems Co., Ltd. that apply on April 20th, 2010, name is called the ITO electrode of describing in patent " self-capacitance touch screen and coordinate data processing method thereof that one-dimensional electrodes is set ", that Chinese Patent Application No. is 201010170919.7, and the whole content of this application (201010170919.7) is included in this with way of reference.By electrode pattern design and electrode control design cleverly, can be so that 3D interaction-electrode 340 can also integrated capacitance touch screen electrode.

Like this, when ITO electrode 311, the corresponding electric signal of ITO electrode 331 biasing make it have 3D Presentation Function, the electric field transmitted layer of 3D interaction-electrode and the electric field receiving layer corresponding electric signal of setovering, so that it has 3D gesture interaction, control function, thereby can realize easily the man-machine interaction of 3D gesture.When ITO electrode 311, the corresponding electric signal of ITO electrode 331 biasing make it have 2D Presentation Function, the electric field transmitted layer of 3D interaction-electrode and electric field receiving layer be biased electrical signal not, ITO electrode 345 biasing corresponding electric signal are so that display device band touch controllable function, thereby can realize easily the man-machine interaction of touch control manner.Therefore, the demonstration that not only realizes 2D/3D is switched, and can between the control of 3D gesture interaction and the mutual control of 2D touch-control, carry out corresponding switching, greatly improves user and experiences.Certainly, which kind of mode man-machine interaction when in fact 3D gesture interaction also can show for 2D, otherwise man-machine interaction when 2D touch-control also can show for 3D, specifically select, and can or use developer select to determine by user.

Continue as shown in Figure 2, in this display device, two dimensional image display module 100 can be TFT-LCD display, these displays self are with layer of polarizer, therefore, layer of polarizer in this two dimension display module 100 is simultaneously as the lower layer of polarizer of parallax barrier in the stereoscopic display device shown in Fig. 2, and integrating device 30 does not need lower layer of polarizer.In other embodiments, when two dimensional image display module 100 is not when with the display of layer of polarizer, for example, plasma display, OLED(Organic Light-Emitting Diode, Organic Light Emitting Diode) display, can also between two dimensional image display module 100 and an ITO conductive glass layer 310, a layer of polarizer be set, this layer of polarizer is as the lower layer of polarizer of 3D grating.

Above example has mainly illustrated 3D grating of the present utility model and the display device that comprises this 3D grating.Although only some of them embodiment of the present utility model is described, those of ordinary skills should understand, and the utility model can be within not departing from its purport and scope be implemented with many other forms.Therefore, the example of showing and embodiment are regarded as illustrative and not restrictive, and in the situation that not departing from the utility model spirit as defined in appended each claim and scope, the utility model may be contained various modifications and replacement.

Claims (10)

1. be integrated with a 3D grating for 3D interaction-electrode, at least comprise setting gradually from the bottom to top:

The first transparent electrode substrate (310),

Liquid crystal layer (320),

The second transparent electrode substrate (330), and

The first layer of polarizer (390);

Wherein, described the first transparent electrode substrate (310), liquid crystal layer (320), the second transparent electrode substrate (330) are used to form the liquid crystal cell of described 3D grating; It is characterized in that, at the upper composition of one side (334) of described the first layer of polarizer of being opposite in of described the second transparent electrode substrate (330) (390), be provided for realizing the 3D interaction-electrode (340) of 3D gesture human-computer interaction function.

2. 3D grating as claimed in claim 1, is characterized in that, described 3D interaction-electrode comprises electric field transmitted layer (344), insulation course (343) and the electric field receiving layer (341,342) setting gradually from the bottom to top.

3. 3D grating as claimed in claim 2, it is characterized in that, described electric field receiving layer comprises formation the first electric field receiving layer (341) and the second electric field receiving layer (342) at grade, described the first electric field receiving layer (341) correspondence is arranged on the border area of described the second transparent electrode substrate (330), and the second electric field receiving layer (342) correspondence is arranged on the middle section of described the second transparent electrode substrate (330).

4. 3D grating as claimed in claim 2, is characterized in that, the thickness range of described insulation course (343) is 10 to 50nm.

5. 3D grating as claimed in claim 2, it is characterized in that, at the upper composition simultaneously of one side (334) of described the first layer of polarizer of being opposite in of described the second transparent electrode substrate (330) (390), be provided for forming the third electrode (345) of capacitance touch screen electrode.

6. 3D grating as claimed in claim 5, is characterized in that, described third electrode (345) is formed on described insulation course (343) with described electric field receiving layer while composition.

7. 3D grating as claimed in claim 6, it is characterized in that, described electric field receiving layer comprises that correspondence is arranged on the first electric field receiving layer (341) of the edge surrounding of described the second transparent electrode substrate (330), and described third electrode (345) correspondence is arranged on the middle section of described the second transparent electrode substrate (330).

8. a display device (30), it is characterized in that, comprise two dimensional image display module and the 3D grating that is integrated with 3D interaction-electrode (340) as described in any one in claim 1 to 7, described 3D grating is placed on described two dimensional image display module (100).

9. display device as claimed in claim 8, is characterized in that, described two dimensional image display module (100) is Thin Film Transistor-LCD, and the layer of polarizer in described Thin Film Transistor-LCD is used as the lower layer of polarizer of 3D grating simultaneously.

10. display device as claimed in claim 8, it is characterized in that, described two dimensional image display module (100) is plasma display or organic light emitting diode display, described 3D grating also comprises the second layer of polarizer being placed under described the first transparent electrode substrate, described the first layer of polarizer is used to form the upper layer of polarizer of described 3D grating, and described the second layer of polarizer is used to form the lower layer of polarizer of described 3D grating.

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