Background technology
Along with information, communications industry are constantly weeded out the old and bring forth the new, (Liquid CrystalDisplay, LCD) market is flourish to have driven LCD.LCD has that high image quality, volume are little, in light weight, low driving voltage, with advantage such as low consumpting power, therefore be widely used in personal digital assistant (Personal Digital Assistant, PDA), mobile phone, shoot with video-corder projector, mobile computer, desktop display, automobile-used display, and consumer communication or electronic product such as projection TV.(these consumer communications or electronic product are also towards light, thin, short, little trend development for Integrated Circuit, IC) advancing by leaps and bounds of industry and LCD manufacturing technology to add integrated circuit.Especially aspect computer product, except high-performance, high-speed desktop PC, mobile computer easy to carry is subjected to paying close attention to greatly and paying attention to especially.
In the development of LCD, be to be the development main shaft with the penetrating LCD at the beginning.The LCD of general penetration is built in the back side of display in its light source, be called backlight (BackLight).So the material of its pixel electrode (Pixel Electrode) must use transparent conductive material, that is tin indium oxide (Indium Tin Oxide, ITO).The employed backlight of penetrating LCD is the maximum assembly of its power consumption in fact, and the field of general LCD widespread use is portable computer and communication product, and using needs battery to supply electric energy often.Therefore how to reduce the power consumption of LCD, become an important research direction.
Therefore reflective LCD arises at the historic moment, and its light source is to utilize external lamp or artificial light source.So the material of pixel electrode must use the conductive material that can reflect external light, generally is to use metallic aluminium.And reflective LCD be in order to reach reflecting effect preferably, and the surface of show electrode is rough.So white light by liquid crystal (Liquid Crystal, LC) during layer, the light path length difference of diverse location, the gait of march of light in the LC layer of adding different frequency is also inconsistent.So, make white light, produce painted phenomenon, influence the color of image by after the LC layer.Be respectively to dispose one deck alignment film at present,, solve white light by painted problem after the LC layer with the orientation of control liquid crystal molecule in the upper and lower plates inboard of LCD.But, reflected displaying device is difficult is issued to height to the requirement of the image of high color quality, especially full-colorization when at high-res.When external light source luminance shortage, the contrast and the brightness of reflected displaying device receive discount greatly, therefore if can cooperate the penetration technology of auxiliary backlight to make semi-penetration semi-reflective (Transflective) display, it can have penetration and reflective advantage simultaneously, be applicable to amorphous silicon film transistor (a-Si TFT) or low-temperature polysilicon film transistor active Driving technique such as (Low Temperature Polysilicon TFT), therefore present low power consumption TA information product mostly adopts the semi-penetrating and semi-reflecting type display panel of this class.
Semi-penetrating and semi-reflecting type display panel can utilize the deficiency of back light system auxiliary environment light source.When environment light source was sufficient, semi-penetrating and semi-reflecting type display panel need not use built-in illuminating source, but made full use of environment light source and can dispense backlight, to reach the effect of power saving.
Please refer to Fig. 1, it illustrates a kind of structural representation of known semi-penetrating and semi-reflective liquid crystal display panel.Known semi-penetrating and semi-reflective liquid crystal display panel 900 includes upper substrate 910, infrabasal plate 920 and liquid crystal layer 930.Upper substrate 910 is parallel with infrabasal plate 920 and is oppositely arranged, and liquid crystal layer 930 is formed between upper substrate 910 and the infrabasal plate 920.On the inside surface of upper substrate 910, that is, be embedded chromatic filter layer (not illustrating) in the black-matrix layer 911, both alignment layers 913 on having on the surface of common electrode layer 912 in the face of the surface of infrabasal plate 920 is provided with black-matrix layer 911 and common electrode layer 912.On the inside surface of infrabasal plate 920, that is, be the pixel region that constitutes arranged by many gate lines that intersect vertically and data line in the face of on the surface of upper substrate 910.Last phase delay chip 914 and last Polarizer 915 are arranged at the outer surface of upper substrate 910 in regular turn.Following phase delay chip 924 and following Polarizer 925 are arranged at the outer surface of infrabasal plate 920 in regular turn.
Each pixel region is controlled by thin film transistor (TFT) TFT (not illustrating), and is divided into penetrating region 940 and echo area 950 at least.Pixel region comprises that transparent electrode layer 921 is positioned on the infrabasal plate 920, and protective seam 922 is positioned on the transparent electrode layer 921.Have reflecting electrode 923 on the protective seam 922 of echo area 950, following both alignment layers 926 is positioned on protective seam 922 and the reflecting electrode 923.Liquid crystal layer 930 is arranged between both alignment layers 913 and the following both alignment layers 926.
Wherein, last phase delay chip 914 and following phase delay chip 924 are quarter-wave lengthy motion picture (λ/4), and it is orthogonal with the polarization direction of following Polarizer 925 to go up Polarizer 915.
Yet when making known half-penetration half-reflection liquid crystal display panel 900, each optical structure layers all must accurately be located and assemble, to avoid influencing optical effect.Therefore, when the optical texture number of layers of display panels 900 the more the time, more increase the manufacturing degree of difficulty and the manufacturing cost of display panels 900.And when reality is used display panels 900, only the light in penetrating region 940 can pass through phase delay chip 924 and following Polarizer 925 down, and the light in echo area 950 passes through phase delay chip 924 and following Polarizer 925 down, that is the light in echo area 950 need not phase delay chip 924 and following Polarizer 925 under the use.Therefore, the optical texture number of layers of known semi-penetrating and semi-reflective liquid crystal display panel 900 still has the space of improvement.
Description of drawings
For above-mentioned and other purposes of the present invention, feature, advantage and embodiment can be become apparent, being described in detail as follows of accompanying drawing:
Fig. 1 is the structural representation that illustrates a kind of known semi-penetrating and semi-reflective liquid crystal display panel.
Fig. 2 is the front schematic view that illustrates according to the liquid crystal indicator of first embodiment of the invention.
Fig. 3 is the diagrammatic cross-section that illustrates according to the display panels of first embodiment of the invention.
Fig. 4 A and 4B illustrate according to the penetrating region of the display panels of first embodiment of the invention and the structural representation of echo area.
Fig. 5 is the structural representation that illustrates according to the penetrating region of the display panels of second embodiment of the invention.
Fig. 6 A and 6B are the structural representations that illustrates according to the echo area of the display panels of third embodiment of the invention.
Fig. 7 is the structural representation that illustrates according to the echo area of the display panels of fourth embodiment of the invention.
Fig. 8 is the structural representation that illustrates according to the echo area of the display panels of fifth embodiment of the invention.
Main description of reference numerals
100: display panels
110,110a, 110b, 110c, 110d: first Polarizer
120: phase delay chip
121,121a: penetrate delay zone
122,122b, 122c, 122d: reflection delay district
Substrate 131 in 130: the first: black-matrix layer
132: 133: the first both alignment layers of common electrode layer
140,140a, 140b, 140c, 140d: liquid crystal layer
Substrate 151 in 150: the second: pixel electrode layer
151a: through electrode 151b: reflecting electrode
160: the second Polarizers
170: pixel region 171: penetrating region
172: the echo area
200: module backlight
900: display panels 910: upper substrate
911: black-matrix layer 912: common electrode layer
913: go up both alignment layers 914: go up phase delay chip
915: go up Polarizer
920: infrabasal plate 921: transparent electrode layer
922: protective seam 923: reflecting electrode
924: following phase delay chip 925: following Polarizer
926: following both alignment layers
930: liquid crystal layer 940: penetrating region
950: the echo area
Embodiment
For above-mentioned and other purposes of the present invention, feature, advantage and embodiment can be become apparent, this instructions will be illustrated especially exemplified by going out some embodiment.But it should be noted that these embodiment, but not in order to limit the present invention just in order to the explanation embodiments of the present invention.
Please refer to Fig. 2, it illustrates the front schematic view according to the liquid crystal indicator of first embodiment of the invention.The liquid crystal indicator of present embodiment includes display panels 100 and module backlight 200.Display panels 100 is arranged at module backlight 200 tops, in order to form semi-penetrating semi-reflecting type liquid crystal displaying device.This module 200 backlight can be side-light type (Edge Lighting) module backlight or straight-down negative light inlet (Bottom Lighting) module backlight, and the module 200 preferable optical diaphragm group (not illustrating) that are provided with wherein backlight are to promote backlight efficiency and collimation.Optical diaphragm group for example can be: diffusion sheet, prismatic lens, inverse edge eyeglass (Turning Prism Sheet), brightness enhancement film (Brightness EnhancementFilm, BEF), reflective brightness enhancement film (Dual Brightness Enhancement Film, DBEF), non-multilayer membrane type reflection Polarizer (Diffused Reflective Polarizer Film, DRPF) or the combination in any of above-mentioned rete.And the light source of module 200 backlight (not illustrating) for example is: cathode fluorescent tube (Cold Cathode Fluorescent Lamp, CCFL), hot-cathode fluorescent lamp (Hot CathodeFluorescent Lamp, HCFL), light emitting diode (Light-Emitting Diode, LED), Organic Light Emitting Diode (Organic Light Emitting Diode, OLED) or EL sheet (Electro-Luminescence, EL), in order to provide backlight to display panels 100.
Please refer to Fig. 3, for illustrating diagrammatic cross-section according to the display panels of first embodiment of the invention.The display panels 100 of present embodiment includes first Polarizer 110, phase delay chip 120, first substrate 130, liquid crystal layer 140, second substrate 150, second Polarizer 160 and a plurality of pixel region 170.Liquid crystal layer 140 is arranged between first substrate 130 and second substrate 150, first Polarizer 110 is arranged at a side of first substrate 130, and with respect to liquid crystal layer 140, phase delay chip 120 is arranged between first Polarizer 110 and first substrate 130, second Polarizer 160 is arranged at a side of second substrate 150, and with respect to liquid crystal layer 140, these pixel regions 170 are formed between first substrate 130 and second substrate 150, wherein these pixel regions 170 each have penetrating region 171 and echo area 172, in order to allow light to pass through respectively and reflection ray.
As shown in Figure 3, the penetrating shaft direction of first Polarizer 110 of present embodiment is perpendicular to the penetrating shaft direction of second Polarizer 160.First substrate 130 is provided with black-matrix layer (Black Matrix) 131, common electrode layer 132 and first both alignment layers 133, and it is arranged at the opposite side (in the face of the direction of liquid crystal layer 140) of first substrate 130 in regular turn.Be embedded with the chromatic filter layer (not illustrating) of colored photo anti-corrosion agent material formation in the black-matrix layer 131 with light transmission, the material of black-matrix layer 131 for example is: metal (for example chromium), graphite or resin type material, thereby first substrate 130 can form colored filter substrate.Common electrode layer 132 is made by the material with electric conductivity and light transmission, for example: ITO, IZO, AZO, GZO, TCO or ZnO.
As shown in Figure 3, second substrate 150 of present embodiment is provided with pixel electrode layer 151, second both alignment layers 152 and many gate lines that intersect vertically and data line (not illustrating), thereby can form thin film transistor (TFT) (TFT) substrate, wherein the pixel electrode layer 151 and second both alignment layers 152 are arranged at the opposite side (in the face of the direction of liquid crystal layer 140) of second substrate 150 in order.These pixel regions 170 of present embodiment are made of the pixel electrode layer 151 of common electrode layer 132, liquid crystal layer 140 and second substrate 150 of first substrate 130.Pixel electrode layer 151 is provided with a plurality of through electrode 151a and a plurality of reflecting electrode 151b, and it corresponds respectively to the penetrating region 171 and the echo area 172 of pixel region 170.Through electrode 151a makes with transparent conductive material, for example: ITO, IZO, AZO, GZO, TCO or ZnO, to allow light penetration.Reflecting electrode 151b makes with the material of high reflectance, for example: metal materials such as Al, Ag, Cr, Mo, Ti or AlNd, in order to reflection ray.
It should be noted that, the thickness of the liquid crystal layer 140 of the penetrating region 171 of present embodiment can be same or different from the thickness of the liquid crystal layer 140 of echo area 172, that is penetrating region 171 can select to have gap of liquid crystal cell identical or inequality (Cell gap) with echo area 172, thereby can form the display panels 100 of the semi-penetration, semi-reflective of monospace or double space.
As shown in Figure 3, the phase delay chip 120 of present embodiment has a plurality of delay zone 121 and a plurality of reflection delay districts 122 of penetrating, these penetrate delay zone 121 each corresponding to each penetrating region 171 of these pixel regions 170, these reflection delay districts 122 each corresponding to each echo area 172 of these pixel regions 170, that is these optical axis directions that penetrate delay zone 121 can be same as or be different from the optical axis direction in these reflection delay districts 122, so that the penetrating region 171 of pixel region 170 can have consistent bright dark attitude performance and light phase with echo area 172.Penetrate delay zone 121 and reflection delay district 122 and can be respectively quarter-wave lengthy motion picture (λ/4), half-wave plate (λ/2), all-wave lengthy motion picture (λ), hollow out zone (being that light directly passes through) or its combination in any, the penetrating shaft direction of its slow-axis direction corresponding to the liquid crystal molecule of liquid crystal layer 140, first Polarizer 110 decides.
As shown in Figure 3, in penetrating region 171, the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140, the penetrating shaft direction of first Polarizer 110 and the optical axis direction that penetrates delay zone 121 of phase delay chip 120 are provided with mutually accordingly, and in echo area 172, the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140, the optical axis direction in the penetrating shaft direction of first Polarizer 110 and the reflection delay district 122 of phase delay chip 120 is provided with mutually accordingly, so that penetrating region has identical bright dark attitude performance with the echo area, and can in display panels 100, only use single phase delay chip 120.Wherein, the penetrating shaft direction of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140 and first Polarizer 110 accompanies first angle (α), the optical axis direction of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140 and phase delay chip 120 accompanies second angle (γ), and light has first phase-delay quantity (δ) after by phase delay chip 120, and light has second phase-delay quantity (π Γ) after by liquid crystal layer 140.And the relation that is provided with between the optical axis direction of the penetrating shaft direction of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140, first Polarizer 110 and phase delay chip 120 can be according to following formula (1) at the light penetration rate T of penetrating region 171 wherein according to the light penetration rate (T) of penetrating region 171 and the light reflectance (R) of echo area 172:
T=[sinδsin(2γ)sin(πΓ)]
2+[sinδsin(2γ-2α)cos(πΓ)-sin(2α)cosδsin(πΓ)]
2 (1)
172 light reflectance (R) is according to following formula (2) in the echo area:
R=[cos(2δ)cos(2πΓ)-sin(2δ)cos(2γ)sin(2πΓ)]
2+{cos(2πΓ)sin(2δ)cos(2γ-2α)+sin(2πΓ)[cos
2(δ)cos(2α)-sin
2(δ)cos(4γ-2α)]}
2 (2)
Therefore, first Polarizer 110, phase delay chip 120 and liquid crystal layer 140 can come corresponding the setting according to the light penetration rate (T) of above-mentioned penetrating region 171 and the light reflectance (R) of echo area 172, use the bright dark attitude performance of control penetrating region 171 and echo area 172.Wherein, can push away by above-mentioned formula (1), when display panels 100 does not apply voltage, and during for bright morphotype formula (when also being normal white mode (Normally White Mode)), can be satisfied with following formula (a) or (b) in the relation that is provided with between delay zone 121 and the liquid crystal layer 140 of penetrating of first Polarizer 110 of penetrating region 171, phase delay chip 120:
sin
2(πΓ)=1,sin
2(2α)=1,sin
2(δ)=0 (a)
sin
2(πΓ)=1,sin
2(2α)=1,sin
2(2γ-2α)=0 (b)
Wherein, in formula (a), second angle (γ) can be arbitrary value, and in formula (b), first phase-delay quantity (δ) can be arbitrary value.
When display panels 100 does not apply voltage, and during for dark morphotype formula when pattern (Normally Block Mode) (also be normal black), can be satisfied with following formula (c) in first Polarizer 110 of penetrating region 171, the relation that is provided with that penetrates between delay zone 121 and the liquid crystal layer 140 of phase delay chip 120:
sin
2(δ)=1,sin
2(2γ-2α)=1,cos
2(πΓ)=0,sin
2(2γ)=0(c)
Can push away by above-mentioned formula (2), when display panels 100 does not apply voltage, and when being bright morphotype formula, can be satisfied with following formula (d) in first Polarizer 110 of echo area 172, the reflection delay district 122 and the relation that is provided with between the liquid crystal layer 140 of phase delay chip 120:
cos(2δ)=0,cos(2γ-2α)=0,cos(2πΓ)=0 (d)
When display panels 100 does not apply voltage, and when being dark morphotype formula, in the reflection delay district 122 of first Polarizer 110 of echo area 172, phase delay chip 120 and the relation that is provided with between the liquid crystal layer 140 can be satisfied with following formula (e), (f), (g), (h) or (i):
sin(2γ-2α)≠0,cos(2πΓ)=0,cos(2α)=0,sin(δ)=0 (c)
sin(2γ-2α)≠0,cos(2πΓ)=0,cos
2(4γ-2α)=0,cos(δ)=0 (f)
sin(2γ-2α)=0,sin(2δ)≠0,cos(2πΓ)=0,cos(2α)=0 (g)
sin(δ)=0,sin(2γ-2α)=0,cos(2πΓ)=0,cos(2α)=0 (h)
cos(δ)=0,sin(2γ-2α)=0,cos(2πΓ)=0,cos(4γ-2α)=0 (i)
Therefore, the display panels 100 of present embodiment can come the various relations that are provided with of corresponding selection by above-mentioned formula (a)~(i), use making penetrating region 171 and echo area 172 have identical bright dark attitude performance, thereby form semi-penetrating and semi-reflective liquid crystal display panel 100.For example when display panels 100 is bright morphotype formula, the relation that is provided with in penetrating region 171 can be by formula (a) and (b) is selected, and the relation that is provided with in echo area 172 can be selected formula (d).
In addition, for example when display panels 100 was normal black pattern, the relation that is provided with in penetrating region 171 can be selected formula (c), and the relation that is provided with in echo area 172 can be by formula (e)~(i) select.
Please refer to Fig. 4 A and 4B, for illustrating according to the penetrating region of the display panels of first embodiment of the invention and the structural representation of echo area.In the present embodiment, further give an example below the relation that is provided with between first Polarizer 110, phase delay chip 120 and the liquid crystal layer 140 that describes display panels 100 in detail.When display panels 100 for example is bright morphotype formula, in penetrating region 171, for example satisfy formula (a), at this moment, the axial level angle that penetrates of first Polarizer 110 is 0 degree, the delay zone 121 that penetrates of phase delay chip 120 can be used as full-wave plate (that is δ=λ), and the level angle that penetrates the optical axis direction of delay zone 121 is 5 degree, the level angle of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140 is negative 45 degree, and light is being λ/2 by the second phase-delay quantity π Γ behind the liquid crystal layer 140.In echo area 172, for example satisfy formula (d), at this moment, the axial level angle that penetrates of first Polarizer 110 is 0 degree, the reflection delay district 122 of phase delay chip 120 can be used as quarter-wave plate (that is δ=λ/4), and the level angle that penetrates the optical axis direction of delay zone 121 is 45 degree, and the level angle of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140 is negative 45 degree, and light is being λ/4 by the second phase-delay quantity π Γ behind the liquid crystal layer 140.Thereby the penetrating region 171 of the display panels 100 of present embodiment and echo area 172 can have identical bright dark attitude performance, to form semi-penetrating and semi-reflective liquid crystal display panel.
Therefore, the display panels 100 of present embodiment and comprise that its display device can penetrate delay zone 121 and reflection delay district 122 by being formed with on single phase delay chip 120, make penetrating region 171 and echo area 172 can have identical bright dark attitude performance to be adjusted at the relation that is provided with between first Polarizer 110, phase delay chip 120 and the liquid crystal layer 140 in penetrating region 171 and the echo area 172 respectively accordingly, to use.Therefore, the semi-penetrating and semi-reflective liquid crystal display panel of present embodiment can only be provided with single phase delay chip, thereby can simplify panel construction and manufacturing process, and then can reduce the product of liquid crystal indicator and the cost of manufacturing.
When the display panels 100 of present embodiment for example is the display panels 100 of monospace, can have the second identical phase-delay quantity (π Γ) at penetrating region 171 with liquid crystal layer 140 in the echo area 172, that is at penetrating region 171 and the identical gap of liquid crystal cell (Cell gap) of liquid crystal layer 140 tools in the echo area 172, thereby can form the display panels 100 of monospace, further simplify technology.At this moment, display panels 100 can be controlled at the bright dark attitude performance of penetrating region 171 and echo area 172 by the relation that is provided with of adjusting first Polarizer 110 and phase delay chip 120.
Please refer to Fig. 5, it illustrates the structural representation according to the penetrating region of the display panels of second embodiment of the invention.Below only describe, do not repeat them here about resemblance with regard to the different place of the present embodiment and first embodiment.Compared to first embodiment, when the display panels 100 of second embodiment for example is bright morphotype formula, in penetrating region 171, for example satisfy formula (b), at this moment, the axial level angle that penetrates of the first Polarizer 110a can be 0 degree, first phase-delay quantity (δ) that penetrates delay zone 121a of phase delay chip 120 can be arbitrary value, that is the delay zone 121a that penetrates of phase delay chip 120 can be quarter-wave lengthy motion picture (λ/4), half-wave plate (λ/2), all-wave lengthy motion picture (λ), the hollow out zone, or its combination in any, and the level angle that penetrates the optical axis direction of delay zone 121a can be 0 degree, the level angle of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140a is negative 45 degree, and light is being λ/2 by second phase-delay quantity (π Γ) behind the liquid crystal layer 140a.
Please refer to Fig. 6 A and Fig. 6 B, it illustrates the structural representation according to the echo area of the display panels of third embodiment of the invention.Below only describe, do not repeat them here about resemblance with regard to the different place of the present embodiment and first embodiment.Compared to first embodiment, when the display panels 100 of the 3rd embodiment for example is dark morphotype formula, in echo area 172, for example satisfy formula (e), at this moment, the axial level angle that penetrates of the first Polarizer 110b can be 0 degree, and the reflection delay district 122b of phase delay chip 120 can be the hollow out zone, the level angle of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140b is negative 45 degree, and light is being λ/4 by second phase-delay quantity (π Γ) behind the liquid crystal layer 140b
At this moment, the reflection delay district 122b of phase delay chip 120 also can be all-wave lengthy motion picture (λ), and the level angle of the optical axis direction of reflection delay district 122b can be 0 degree.
Please refer to Fig. 7, it illustrates according to the display panels of the fourth embodiment of the invention structural representation in the echo area.Below only describe, do not repeat them here about resemblance with regard to the different place of the present embodiment and first embodiment.Compared to first embodiment, when the display panels 100 of the 4th embodiment for example is dark morphotype formula, in echo area 172, for example satisfy formula (f), at this moment, the axial level angle that penetrates of the first Polarizer 110c can be 45 degree, the reflection delay district 122c of phase delay chip 120 can be half-wave plate (λ/2), and the level angle of the optical axis direction of reflection delay district 122c can be 22.5 degree, the level angle of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140c is negative 45 degree, and light is being λ/4 by second phase-delay quantity (π Γ) behind the liquid crystal layer 140c.
Please refer to Fig. 8, it illustrates according to the display panels of the fifth embodiment of the invention structural representation in the echo area.Below only describe, do not repeat them here about resemblance with regard to the different place of the present embodiment and first embodiment.Compared to first embodiment, when the display panels 100 of the 5th embodiment for example is dark morphotype formula, in echo area 172, for example satisfy formula (h) or (i), at this moment, the axial level angle that penetrates of the first Polarizer 110d can be 0 degree, the reflection delay district 122d of phase delay chip 120 can be half-wave plate (λ/2), and the level angle of the optical axis direction of reflection delay district 122d can be 0 degree, the level angle of the slow-axis direction of the liquid crystal molecule of liquid crystal layer 140d is negative 45 degree, and light is being λ/4 by second phase-delay quantity (π Γ) behind the liquid crystal layer 140d.
By the embodiment of the invention described above as can be known, display panels of the present invention and the display device that comprises it can be adjusted at the relation that is provided with between first Polarizer, phase delay chip and the liquid crystal layer in penetrating region and the echo area respectively accordingly, use making penetrating region and echo area can have identical bright dark attitude performance.Therefore, the display panels of the semi-penetration, semi-reflective of present embodiment can only use single phase delay chip, thereby can simplify panel construction and technology.And can select to form the display panels of monospace, with further simplification technology.
Though the present invention discloses as above with embodiment; right its is not in order to limit the present invention; any those skilled in the art without departing from the spirit and scope of the present invention; can carry out various changes and retouching, thus protection scope of the present invention when with appended claims and equivalent thereof the person of being defined be as the criterion.