CN204903921U - Array substrate and display device - Google Patents

Abstract

The application discloses array substrate, including pixel array structure, the scanning line and with the data line of the insulating cross arrangement of scanning line, its characterized in that, pixel array structure includes a plurality of pixel, pixel includes first sub -pixel, second sub -pixel and third sub -pixel, and first sub -pixel is 3 for the length -width ratio: 1 the rectangle, second sub -pixel and third sub -pixel are the same rectangle, coincide in each long limit of second sub -pixel and third sub -pixel, and each minor face of second sub -pixel and third sub -pixel is all adjacent with first sub -pixel's same long limit, adjacent pixel's second sub -pixel and third sub -pixel sets up to second colour and third colour in turn in the scanning line orientation, and just second sub -pixel among the same pixel and third sub -pixel are mutual not homochromy, two adjacent in data line orientation pixel are crisscross along the scanning line orientation, and homochromy and long limit has the sub -pixel electricity of overlapping to connect. The utility model provides an array substrate has optimized the precision that the pure color single -point shows.

Description

A kind of array base palte and display device

Technical field

The application relates to electronic technology field, is specifically related to display technique field, particularly relates to a kind of array base palte and the display device comprising this array base palte.

Background technology

Along with people are to the continuous pursuit of display frame quality, the display screen of high PPI (PixelsPerInch, the pixel quantity of per inch) has become one of configuration of various display terminal indispensability.Although the display screen of high PPI can provide the picture of finer and smoother fineness, but the sub-pixel needed for display panel, data line and sweep trace showed increased, the penetrance of display panel can be caused to decline to a great extent, the problem that power consumption, technology difficulty and manufacturing cost all significantly increase.

In the prior art, use sub-pixel to play up (SubPixelRendering, SPR) technology, by RGB sub-pixel of rationally arranging on the product of low PPI, and combine the algorithm adapted, make it have the display effect of high PPI.Fig. 1 is the schematic diagram of a kind of pel array RGBG (RedGreenBlueGreen, red, green, the blue and green) structure using sub-pixel rendering intent in prior art.As shown in Figure 1, in RGBG structure, red sub-pixel and green sub-pixels form the first sub-pixel unit, blue subpixels and green sub-pixels form the second sub-pixel unit, and the first sub-pixel unit and the second sub-pixel unit are alternately arranged on scan-line direction and on data line direction.First sub-pixel unit and the second sub-pixel unit share red sub-pixel and blue subpixels mutually.Redness (R) sub-pixel of RGBG structure and blue (B) sub-pixel length breadth ratio (a:b) 3:2, the length breadth ratio of green (G) sub-pixel is (a:c) 3:1.The length breadth ratio used relative to RealRGB (RedGreenBlue, RGB) structure is as shown in Figure 3 a the sub-pixel of 3:1, and when sub-pixel length is fixing, its actual PPI reduces 1/3, and data line is also corresponding decreases 1/3.Further, after collocation reasonable algorithm, the picture element array structure of this low resolution can realize the display effect of high PPI (length breadth ratio of sub-pixel is 3:1) equally.

But this picture element array structure exists problem below: cannot show pure color single-point accurately, namely one-dimensional pixel plays up a point that can only show in adjacent two pure color single-points, and bidimensional is played up and is caused single-point to show diffusion increasing the weight of.

Utility model content

The object of the application is to propose a kind of array base palte and display device, thus solves at least one technical matters as above.

On the one hand, this application provides a kind of array base palte, comprise substrate, described substrate is provided with picture element array structure, and sweep trace and insulating data line arranged in a crossed manner with described sweep trace, described picture element array structure comprises multiple pixel cell;

Described pixel cell comprises the first sub-pixel, the second sub-pixel and the 3rd sub-pixel, the rectangle of described first sub-pixel to be length breadth ratio be 3:1, and the long limit of wherein said first sub-pixel is parallel with described data line, and the color of described first sub-pixel is the first color;

Described second sub-pixel is the rectangle that shape is identical with the 3rd sub-pixel, and the long limit of described rectangle is parallel with described sweep trace;

The length ratio on the length of the minor face of described second sub-pixel and the long limit of described first sub-pixel is 1:2;

A long limit of described second sub-pixel and one of described 3rd sub-pixel long limit overlap, a minor face of described second sub-pixel and a minor face of described 3rd sub-pixel are all disposed adjacent with the same long limit of described first sub-pixel, and described second sub-pixel is parallel with described sweep trace with the line of the geometric center of the first sub-pixel with the mid point of the line of described 3rd sub-pixel geometric center;

On scan-line direction, described second sub-pixel of adjacent two described pixel cells and described 3rd sub-pixel are alternatively set as the second color and the 3rd color, and described second sub-pixel in same pixel cell and the 3rd sub-pixel colors different;

Two described pixel cells adjacent on data line direction are crisscross arranged along scan-line direction, and there is overlapping sub-pixel electrical connection on the identical and long limit of the color of two described pixel cells adjacent on data line direction.

The application another aspect provides a kind of display device, and described display device comprises described array base palte.

The array base palte that the application provides and display device, first sub-pixel A achieves horizontal interlocking, second sub-pixel B and the 3rd sub-pixel C achieves longitudinal interlocking, add the contact range of the second sub-pixel B and the 3rd sub-pixel C, compared with the RGBG structure of prior art, add rendering capability, algorithm decreases the selection range of minimum display unit, contribute to algorithm development, single-point display precision can be improved simultaneously.

Accompanying drawing explanation

By reading the detailed description done non-limiting example done with reference to the following drawings, the other features, objects and advantages of the application will become more obvious:

Fig. 1 is a kind of RGBG structural representation adopting pixel rendering in prior art;

Fig. 2 is the schematic diagram of the structure of the embodiment of the application's array base palte;

Fig. 2 a is each arrangement of subpixels schematic diagram of pixel cell in the embodiment of the application's array base palte;

Fig. 3 A is the pixel distribution schematic diagram of RealRGB dot structure;

Fig. 3 B shares relation schematic diagram between the pixel distribution schematic diagram of the application's array base palte embodiment and pixel;

Fig. 3 C is the first pixel of the application's array base palte embodiment and the schematic diagram of the second pixel.

Embodiment

Below in conjunction with drawings and Examples, the application is described in further detail.Be understandable that, specific embodiment described herein is only for explaining related invention, but not the restriction to this invention.It also should be noted that, for convenience of description, in accompanying drawing, illustrate only the part relevant to Invention.

It should be noted that, when not conflicting, the embodiment in the application and the feature in embodiment can combine mutually.Below with reference to the accompanying drawings and describe the application in detail in conjunction with the embodiments.

Please refer to Fig. 2, it illustrates the structural representation of the embodiment of the array base palte of the application.

As shown in Figure 2, the array base palte of the present embodiment comprises, the picture element array structure 20 that the substrate of array base palte is arranged, and to the data line (not providing in figure) that picture element array structure provides the sweep trace of electric signal and insulate arranged in a crossed manner with sweep trace.Picture element array structure 20 comprises the pixel cell 201 of multiple repeated arrangement, and pixel cell 201 comprises the first sub-pixel A, the second sub-pixel B and the 3rd sub-pixel C.The shape of the first sub-pixel A is rectangle, and its long edge lengths a1 is 3:1 with the ratio of bond length b1, and the long limit of the first sub-pixel A is parallel with data line.The shape of the second sub-pixel B and the 3rd sub-pixel C is also rectangle, and the second sub-pixel B is identical with the shape of the 3rd sub-pixel C.The long limit of the second sub-pixel B is parallel with sweep trace.The bond length b2 of the second sub-pixel B is 1:2 with the ratio of the long edge lengths a1 of the first sub-pixel A.

As Fig. 2 a shows, in a pixel cell 201, the Rankine-Hugoniot relations of the first sub-pixel A, the second sub-pixel B and the 3rd sub-pixel C: the long limit L2 of the second sub-pixel B and the long limit L3 of the 3rd sub-pixel C overlaps, the minor face S1 of the second sub-pixel B and the minor face S2 of the 3rd sub-pixel C is adjacent with the same long limit L1 of the first sub-pixel respectively.Further, in a pixel cell 201, the geometric center O of the second sub-pixel B ₂with the geometric center O of the 3rd sub-pixel C ₃the mid point O of line ₄with the geometric center O of the first sub-pixel A ₁line parallel with sweep trace.

As shown in Figure 2, two pixel cells 201 and 201 ' adjacent on scan-line direction, the color of the first sub-pixel A is the first color, the color of the second sub-pixel B is alternatively set as the second color and the 3rd color, the color of the 3rd sub-pixel C is alternatively set as the second color and the 3rd color, and in same pixel cell 201, the color of the second sub-pixel B and the 3rd sub-pixel C is different.That is, in same pixel cell 201, first sub-pixel A, the second sub-pixel B and the 3rd sub-pixel C color different, the color of the first sub-pixel A is the first color, the color of the second sub-pixel B and the color of the 3rd sub-pixel C be respectively in the second color and the 3rd color any one; In any two pixel cells adjacent along sweep trace in 201 and 201 ', the color of the first sub-pixel A is identical, is the first color; In pixel cell 201, the color of the second sub-pixel B is identical with the color of the 3rd sub-pixel C in pixel cell 201 ', is the one in the second color and the 3rd color; In pixel cell 201, the color of the 3rd sub-pixel C is identical with the color of the second sub-pixel B in pixel cell 201 ', is the one in the second color and the 3rd color.Like this, the color of the second sub-pixel B of any two pixel cells adjacent on scan-line direction is different, the color of the 3rd sub-pixel C is different, and the color of the second sub-pixel B wherein in a pixel cell and the color of the 3rd sub-pixel C are identical with the color of the second sub-pixel B with the color of the 3rd sub-pixel C in one other pixel unit respectively.

As shown in Figure 2, two pixel cells 201 and 201 adjacent on the data line " to interlock along scan-line direction, staggered distance is designated as d.That is, two pixel cells 201 and 201 adjacent on the data line " be non-alignment; namely; two pixel cells 201 and 201 adjacent on the data line ", the long limit L1 of the first sub-pixel A of pixel cell 201 and pixel cell 201 " the long limit L1 of the first sub-pixel A be arranged on the different straight lines parallel with data line.Pixel cell 201 " the straight line at L1 place, long limit of the first sub-pixel A can be positioned at the left side of the straight line at the L1 place, long limit of the first sub-pixel A of pixel cell 201; also can be positioned at the right side of the straight line at the L1 place, long limit of the first sub-pixel A of pixel cell 201, not limit here.

The long edge lengths of the second sub-pixel B is designated as a2, then, pixel cell 201 and 201 " staggered distance d for being greater than the bond length of the first sub-pixel, and any number of the long edge lengths of the second sub-pixel can be less than.In so staggered picture element array structure, the second sub-pixel B and 201 of pixel cell 201 li " the 3rd sub-pixel C color identical; and there is overlap on long limit; arrange the second sub-pixel B and 201 of pixel cell 201 li " the 3rd sub-pixel C share a sweep trace and a data lines, show time, the second sub-pixel B in pixel cell 201 and pixel cell 201 " in the 3rd sub-pixel C can as a sub-pixel.That is, in two pixel cells adjacent on data line direction, long limit overlap and the identical sub-pixel of color owing to sharing a sweep trace and a data lines, when showing, can as a sub-pixel.Such wiring, can reduce sweep trace and the data line of driven element pixel, is conducive to improving penetrance.

In an optional manner of the present embodiment, the long edge lengths a2 of the second sub-pixel B is 4:3 with the ratio of bond length b2, and meanwhile, the staggered distance d between two pixel cells adjacent on data line direction is 3/4 of the long edge lengths of the second sub-pixel.

Those skilled in the art the size of just the first sub-pixel number how many according to required pixel can do necessary adjustment, meet the dimension scale relation of the first sub-pixel, the second sub-pixel and the 3rd sub-pixel, and the second sub-pixel picture element array structure that namely can realize different pixels point requirement identical with the 3rd sub-pixel shape.

In an Alternate embodiments of the present embodiment, the first color is green, and the second color and the 3rd color are respectively the one in red and blueness.Like this, around red sub-pixel and blue subpixels around green sub-pixels, different color effects can be realized according to the different GTGs of three colors, pure color single-point picture can be shown accurately.

The array base palte that the embodiment of the present application provides, first sub-pixel A achieves horizontal interlocking, second sub-pixel B and the 3rd sub-pixel C achieves longitudinal interlocking, add the contact range of the second sub-pixel B and the 3rd sub-pixel C, add rendering capability, algorithm decreases the selection range of minimum display unit, contributes to algorithm development, can improve single-point display precision simultaneously.

It should be noted that, picture element array structure described in above-described embodiment had both been applicable to LCDs (LiquidCrystalDisplay, LCD), Organic Light Emitting Diode (OrganicLight-EmittingDiode, OLED) display screen is also applicable to.For LCD, the pel array in the array base palte described in above-mentioned any embodiment, can as the foundation configuring thin film transistor (TFT) (ThinFilmTransistor, TFT) and color film.For OLED, the pel array in the array base palte described in above-mentioned any embodiment, can as the foundation being configured with OLED size and distribution.

The present embodiment also provides a kind of display device, this display device comprises the array base palte of above-described embodiment, an Alternate embodiments of above-mentioned display device is liquid crystal indicator, and another Alternate embodiments of above-mentioned display device is organic electroluminescence display device and method of manufacturing same.

Present invention also provides a kind of driving method of display device, be applied to the display device in above-described embodiment.In the display device of above-described embodiment, the first sub-pixel is the first color, and the color of the second sub-pixel is the second color, and the color of the 3rd sub-pixel is the 3rd color, and the color of described 4th sub-pixel is the 4th color.Described display device comprises control chip, and described control chip comprises the first signal processing part and secondary signal handling part;

Described control chip receives the first display picture data of described display panel, and described first display picture data comprises the first brightness value of the first color, the second color and the 3rd color sub-pixels; Described first display picture data obtains the second display picture data through the described first signal processing part conversion of described control chip, and described second display picture data comprises the second brightness value of the first color, the second color, the 3rd color and the 4th color sub-pixels; Described second display picture data converts through the described secondary signal handling part of described control chip and obtains the brightness data of described first pixel sub-pixel, and the brightness data of the sub-pixel of described first pixel exports to described display panel by described control chip.

Display picture data obtains the brightness data of pixel cell sub-pixel through the conversion of control chip, and the brightness data of sub-pixel exports to display panel by control chip, realizes the driving of each sub-pixel in display panel.

Using the brightness value of sub-pixel each in display picture data as the first brightness value, in the display device of the embodiment of the present application drawn that converts, the brightness value of each sub-pixel is as the second brightness value

The data corresponding relation of control chip conversion method in above-mentioned driving method is described in detail below in conjunction with Fig. 3 A and Fig. 3 B.

Fig. 3 A is the schematic diagram of the display device of existing RealRGB rectangle pixel arrangement.

In the present embodiment, display picture data can represent with formula (1):

$\left[\begin{array}{ccccccc}{X}_{11}& Y_{12}& Z_{13}& ...& X_{1\left(n-2\right)}& Y_{1\left(n-1\right)}& Z_{1n}\\ X_{21}& Y_{22}& Z_{23}& ...& X_{2\left(n-2\right)}& Y_{2\left(n-1\right)}& Z_{2n}\\ X_{31}& Y_{32}& Z_{33}& ...& X_{3\left(n-2\right)}& Y_{3\left(n-1\right)}& Z_{3n}\\ ...& ...& ...& ...& ...& ...& ...\\ X_{\left(m-2\right)1}& Y_{\left(m-2\right)2}& Z_{\left(m-2\right)3}& ...& X_{\left(m-2\right)\left(n-2\right)}& Y_{\left(m-2\right)\left(n-1\right)}& Z_{\left(m-2\right)n}\\ X_{\left(m-1\right)1}& Y_{\left(m-1\right)2}& Z_{\left(m-1\right)3}& ...& X_{\left(m-1\right)\left(n-2\right)}& Y_{\left(m-1\right)\left(n-1\right)}& Z_{\left(m-1\right)n}\\ X_{m1}& Y_{m2}& Z_{m3}& ...& X_{m\left(n-2\right)}& Y_{m\left(n-1\right)}& Z_{mn}\end{array}\right]---\left(1\right)$

Wherein, X ₁₁..., X _{1 (n-2)}..., X _m1..., X _{m (n-2)}for the first brightness value of the sub-pixel of the first color in display picture data, Y ₁₂..., Y _{1 (n-1)}..., Y _m2..., Y _{m (n-1)}for the first brightness value of the sub-pixel of the second color in display picture data, Z ₁₃..., Z _1n..., Z _m3..., Z _mnfor the first brightness value of the sub-pixel of the 3rd color in display picture data, m, n are respectively line number and the columns of display picture data.

As shown in Figure 3A, the display picture data of formula (1) can be represented by the array of sub-pixels shown in 3a.Array of sub-pixels 3a can comprise multiple display unit, such as 311 shown in Fig. 3 A, 312,313,314,315,316,317,318,319,320,321 and 322 etc.Each display unit comprises a brightness center, and the brightness center of display unit 311,312,313,314,315,316,317,318,319,320,321 and 322 is respectively 3110,3120,3130,3140,3150,3160,3170,3180,3190,3200,3210 and 3220.

By the brightness center translation shown in Fig. 3 A in Fig. 2, can obtain the brightness central distribution figure of the present embodiment, as shown in Figure 3 B.As can be seen from Fig. 3 B, brightness center 33 be arranged on data line direction the first sub-pixel A geometric center or along on the mid point of the geometric center line of adjacent two the first sub-pixel A of scan-line direction.In 3B, a display unit can be determined in each brightness center 33.Carry out sub-pixel in the present embodiment when playing up, display unit can be seen as a virtual pixel, but not the physical picture element of reality point.By sharing physical picture element point between multiple display unit, the display PPI higher than physics PPI can be realized.In the present embodiment, comprise multiple the first virtual pixel 341 and the second pixel 342 as shown in Figure 3 C.The brightness center 33 of the first pixel 341 is positioned at the geometric center of the first sub-pixel A, and the brightness center 33 of the second pixel 342 is located on the mid point of the geometric center line of two the first sub-pixel A adjacent on scan-line direction.

As shown in FIG. 3 C, the first pixel 341 comprises: a pixel cell, first sub-pixel be disposed adjacent on scan-line direction with pixel cell, and two sub-pixels be electrically connected with the second sub-pixel and the 3rd sub-pixel of pixel cell respectively.

As shown in FIG. 3 C, the second pixel 342 comprises: pixel cell, respectively have with the second sub-pixel of pixel cell and the 3rd sub-pixel be electrically connected two sub-pixels, second sub-pixel adjacent with pixel cell and the 3rd sub-pixel and respectively and second sub-pixel adjacent with pixel cell and the 3rd sub-pixel have two sub-pixels be electrically connected.

In the present embodiment, as shown in Figure 3 B, as in figure with first pixel 3411 and 3412 of adjacent two that solid box goes out, the second sub-pixel B (representing with alphabetical K in figure) is shared between first pixel 3411 and 3412, the sub-pixel (also representing with K in figure) be electrically connected with the second sub-pixel K, 3rd sub-pixel C (representing with letter e in figure) and the sub-pixel (also representing with E in figure) be electrically connected with the 3rd sub-pixel C, in figure, solid box has gone out other two adjacent the second pixels 3421 and 3422, a first sub-pixel A (representing with N in figure) is shared between second pixel 3421 and 3422, between the first pixel 3411 adjacent on data line direction and the second pixel 3422 share a second sub-pixel B and with the second sub-pixel B (representing with alphabetical K in figure).

Composition graphs 3A and Fig. 3 B describes the computation process of first pixel 3411 of the present embodiment and each sub-pixel of the second picture 3421 vegetarian refreshments in detail:

The brightness center 3150 and 3180 in corresponding diagram 3A is distinguished at the brightness center 331 of the first pixel 3411 in Fig. 3 B and the brightness center 332 of the second pixel 3421,

Suppose that the color of the sub-pixel 3111 in Fig. 3 A in display unit 311 is the second color, the color of sub-pixel 3112 is the first color, the color of sub-pixel 3113 is the 3rd color, in Fig. 3 B in the first pixel or the second pixel, the color of the first sub-pixel A is the first color, the color of the second sub-pixel B and the 3rd sub-pixel is respectively the second color and the 3rd color, or the color of the second sub-pixel B and the 3rd sub-pixel C is respectively the 3rd color and the second color.

In figure 3 a, the first brightness value of each sub-pixel of display unit 311,312,313,314,315,316,317,318,319,320,321 and 322 can form the matrix such as formula (2):

$\left[\begin{array}{ccccccccc}{X}_{kl}& Y_{k\left(l+1\right)}& Z_{k\left(l+2\right)}& X_{k\left(l+3\right)}& Y_{k\left(l+4\right)}& Z_{k\left(l+5\right)}& X_{k\left(l+6\right)}& Y_{k\left(l+7\right)}& Z_{k\left(l+8\right)}\\ X_{\left(k+1\right)l}& Y_{\left(k+1\right)\left(l+1\right)}& Z_{\left(k+1\right)\left(l+2\right)}& X_{\left(k+1\right)\left(l+3\right)}& Y_{\left(k+1\right)\left(l+4\right)}& Z_{\left(k+1\right)\left(l+5\right)}& X_{\left(k+1\right)\left(l+6\right)}& Y_{\left(k+1\right)\left(l+7\right)}& Z_{\left(k+1\right)\left(l+8\right)}\\ X_{\left(k+2\right)l}& Y_{\left(k+2\right)\left(l+1\right)}& Z_{\left(k+2\right)\left(l+2\right)}& X_{\left(k+2\right)\left(l+3\right)}& Y_{\left(k+2\right)\left(l+4\right)}& Z_{\left(k+2\right)\left(l+5\right)}& X_{\left(k+2\right)\left(l+6\right)}& Y_{\left(k+2\right)\left(l+7\right)}& Z_{\left(k+2\right)\left(l+8\right)}\\ X_{\left(k+3\right)l}& Y_{\left(k+3\right)\left(l+1\right)}& Z_{\left(k+3\right)\left(l+2\right)}& X_{\left(k+3\right)\left(l+3\right)}& Y_{\left(k+3\right)\left(l+4\right)}& Z_{\left(k+3\right)\left(l+5\right)}& X_{\left(k+3\right)\left(l+6\right)}& Y_{\left(k+3\right)\left(l+7\right)}& Z_{\left(k+3\right)\left(l+8\right)}\end{array}\right]---\left(2\right)$

Wherein, the line number of the sub-pixel that k, l are respectively the second color in display unit 311 in array of sub-pixels 3A and columns, X _kl, Y _{k (l+1)}, Z _{k (l+2)}be respectively the first brightness value of the sub-pixel of the second color in display unit 311, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{k (l+3)}, Y _{k (l+4)}, Z _{k (l+5)}; Be respectively the first brightness value of the sub-pixel of the second color in display unit 312, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{k (l+6)}, Y _{k (l+7)}, Z _{k (l+8)}be respectively the first brightness value of the sub-pixel of the second color in display unit 313, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+1) l}, Y _{(k+1) (l+1)}, Z _{(k+1) (l+2)}be respectively the first brightness value of the sub-pixel of the second color in display unit 314, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+1) (l+3)}, Y _{(k+1) (l+4)}, Z _{(k+1) (l+5)}be respectively the first brightness value of the sub-pixel of the second color in display unit 315, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+1) (l+6)}, Y _{(k+1) (l+7)}, Z _{(k+1) (l+8)}be respectively the first brightness value of the sub-pixel of the second color in display unit 316, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+2) l}, Y _{(k+2) (l+1)}, Z _{(k+2) (l+2)}be respectively the first brightness value of the sub-pixel of the second color in display unit 317, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+2) (l+3)}, Y _{(k+2) (l + 4)}, Z _{(k+2) (l+5)}be respectively the first brightness value of the sub-pixel of the second color in display unit 318, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+2) (l+6)}, Y _{(k+2) (l+7)}, Z _{(k+2) (l+8)}be respectively the first brightness value of the sub-pixel of the second color in display unit 319, the sub-pixel of the first color, the sub-pixel of the 3rd color, X _{(k+3) l}, Y _{(k+3) (l+1)}, Z _{(k+3) (l+2)}be respectively the first brightness value of the sub-pixel of the second color in display unit 320, the sub-pixel of the first color, the sub-pixel of the 3rd color; X _{(k+3) (l+3)}, Y _{(k+4) (l+4)}, Z _{(k+5) (l+5)}be respectively the first brightness value of the sub-pixel of the second color in display unit 321, the sub-pixel of the first color, the sub-pixel of the 3rd color.

As shown in Figure 3 B, the first pixel 3411 is made up of the first sub-pixel J, sub-pixel group E, F, D and K, and wherein D, E, F, K comprise the sub-pixel of two electrical connections respectively.

Suppose that the color of the first sub-pixel J is the first color, the color of sub-pixel group E and F is the second color, and the color of sub-pixel group D and K is the 3rd color.J1 represents the second brightness value of the first color, the second brightness value of E1, F1 generation table the second color, and D1, K1 represent the second brightness value of the 3rd color,

The second brightness value then calculating 3411 each sub-pixels of the first pixel is as follows:

D1＝Z _k(l+5)×α+(Z _(k+1)(l+2)+Z _(k+1)(l+5))×β；(3)

F1＝X _(k+2)l×α+(X _(k+1)l+X _(k+1)(l+3))×β；(4)

J1＝Y _(k+1)(l+4)；(5)

E1＝X _k(l+6)×α+(X _(k+1)(l+3)+X _(k+1)(l+6))×β；(6)

K1＝Z _(k+2)(l+5)×α+(Z _(k+1)(l+5)+Z _(k+1)(l+8))×β；(7)

In formula, 0< α <1,0< β <1.

As shown in Figure 3 B, the second pixel 3421 is by the first sub-pixel L and G, sub-pixel group M and K, and wherein M and K comprises the sub-pixel of two electrical connections respectively.Suppose in the second pixel 3421, the color of L and G is the first color, and the color of M is the second color, and the color of K is the 3rd color.L1, G1 represent the second brightness value of the first color, and M1 represents the second brightness value of the second color, and K1 represents the second brightness value of the 3rd color,

The second brightness value calculating 3421 each sub-pixels of the second pixel is as follows:

K1＝Z _(k+2)(l+5)×α+(Z _(k+1)(l+5)+Z _(k+1)(l+8))×β；(8)

L1＝(Y _(k+2)(l+1)+Y _(k+2)(l+4))×η；(9)

M1＝X _(k+2)(l+3)×η+(X _(k+3)l+X _(k+3)(l+3))×ξ；(10)

G1＝(Y _(k+2)(l+4)+Y _(k+2)(l+7))×η；(11)

In formula, 0< η <1,0< ξ <1

More than describe and be only the preferred embodiment of the application and the explanation to institute's application technology principle.Those skilled in the art are to be understood that, utility model scope involved in the application, be not limited to the technical scheme of the particular combination of above-mentioned technical characteristic, also should be encompassed in when not departing from the design of described utility model, other technical scheme of being carried out combination in any by above-mentioned technical characteristic or its equivalent feature and being formed simultaneously.The technical characteristic that such as, disclosed in above-mentioned feature and the application (but being not limited to) has similar functions is replaced mutually and the technical scheme formed.

Claims (11)

1. an array base palte, comprises substrate, and described substrate is provided with picture element array structure, and sweep trace and insulating data line arranged in a crossed manner with described sweep trace, and it is characterized in that, described picture element array structure comprises multiple pixel cell;

Described pixel cell comprises the first sub-pixel, the second sub-pixel and the 3rd sub-pixel, the rectangle of described first sub-pixel to be length breadth ratio be 3:1, and the long limit of wherein said first sub-pixel is parallel with described data line, and the color of described first sub-pixel is the first color;

Described second sub-pixel is the rectangle that shape is identical with the 3rd sub-pixel, and the long limit of described rectangle is parallel with described sweep trace;

The length ratio on the length of the minor face of described second sub-pixel and the long limit of described first sub-pixel is 1:2;

A long limit of described second sub-pixel and one of described 3rd sub-pixel long limit overlap, a minor face of described second sub-pixel and a minor face of described 3rd sub-pixel are all disposed adjacent with the same long limit of described first sub-pixel, and described second sub-pixel is parallel with described sweep trace with the line of the geometric center of the first sub-pixel with the mid point of the line of described 3rd sub-pixel geometric center;

On scan-line direction, described second sub-pixel of adjacent two described pixel cells and described 3rd sub-pixel are alternatively set as the second color and the 3rd color, and described second sub-pixel in same pixel cell and the 3rd sub-pixel colors different;

Two described pixel cells adjacent on data line direction are crisscross arranged along scan-line direction, and there is overlapping sub-pixel electrical connection on the identical and long limit of the color of two described pixel cells adjacent on data line direction.

2. array base palte according to claim 1, is characterized in that, described staggered distance is greater than zero, is less than the length on the described second long limit of sub-pixel.

3. array base palte according to claim 2, is characterized in that, described staggered distance is 3/4 of the long edge lengths of described second sub-pixel.

4. array base palte according to claim 1, is characterized in that, the ratio of the long limit of described second sub-pixel and the minor face of described second sub-pixel is 4:3.

5. array base palte according to any one of claim 1 to 4, is characterized in that, described first color is green, described second color and the 3rd color be respectively in red and blueness any one, and the second color and the 3rd color different.

6. array base palte according to claim 5, is characterized in that, comprises multiple brightness center, and described brightness center is uniformly distributed on described picture element array structure;

Described brightness center be disposed alternately at along described data line direction described first sub-pixel geometric center and any two along on the mid point of the connecting line of the geometric center of adjacent described first sub-pixel of described scan-line direction.

7. array base palte according to claim 6, is characterized in that, described picture element array structure comprises multiple first pixel and multiple second pixel, and the described brightness in described first pixel is centrally located on described first sub-pixel; Described brightness in described second pixel be centrally located at described any two along on the mid point of the connecting line of the geometric center of adjacent described first sub-pixel of described scan-line direction.

8. array base palte according to claim 7, it is characterized in that, described first pixel comprises: a described pixel cell, first sub-pixel be disposed adjacent at scan-line direction with described pixel cell, and two sub-pixels be electrically connected with the second sub-pixel and the 3rd sub-pixel of described pixel cell respectively.

9. array base palte according to claim 8, it is characterized in that, described second pixel comprises: described pixel cell, be respectively electrically connected with the second sub-pixel of described pixel cell and the 3rd sub-pixel two sub-pixels, second sub-pixel adjacent with described pixel cell and the 3rd sub-pixel and respectively and second sub-pixel adjacent with described pixel cell and the 3rd sub-pixel have two sub-pixels be electrically connected.

10. a display device, comprises the array base palte as described in claim 1 to 9.

11. display device according to claim 10, is characterized in that, described display device is organic electroluminescence display device and method of manufacturing same or liquid crystal indicator.