CN1544979A - Thin film transistor liquid crystal display with locality multi-domain perpendicular direction matching mode - Google Patents

Abstract

The invention is a thin-film transistor LCD wiht partial multizone vertical allocation mode, especially a reflecting structure as well as a structure of semipermeable semireflecting film LCD with partial multizone vertical allocation mode in the reflecting area. By making the interconnected conductive raised point electrode on the reflecting plate with raised points, or/and by forming a corresponding hole at the transparent electrode of the top basal plate at each raised point in the reflecting plate, it can not only make the liquid crystal layer of the vertical epitaxial reflecting TFT-LCD or the reflecting area of the semipermeable semireflecting TFT-LCD formed with liquid crystal distribution in partial continuous multizone vertical allocation mode, but also has wider visual angle and has no influence on primary reflecting light guiding function of the raised points.

Description

Has locality multi-zone vertical alignment nematic pattern Thin Film Transistor-LCD

Technical field

The present invention has locality (local) multi-zone vertical alignment nematic pattern (Multi-DomainVertical Alignment Mode about a kind of; MVA) reflective Thin Film Transistor-LCD and the semi-penetration, semi-reflective Thin Film Transistor-LCD that has locality MVA pattern in the echo area, especially refer to a kind of at reflective Thin Film Transistor-LCD with in the echo area of semi-penetration, semi-reflective Thin Film Transistor-LCD, make interconnected conductive bumps point electrode, or/and form the structure of a corresponding broken hole at the upper substrate transparency electrode place of each the prominent some position that corresponds to reflecting plate.

Background technology

Quick progress along with the thin film transistor (TFT) manufacturing technology, possessed the LCD of advantages such as frivolous, power saving, no width of cloth ray, a large amount of is applied in the various electronic products such as counter, personal digital aid (PDA) (PDA), wrist-watch, mobile computer, digital camera and mobile phone.Add the positive input research and development of industry and adopt the production equipment that maximizes, the production cost of LCD is constantly descended, more make the demand of LCD heighten.

Thin Film Transistor-LCD (TFT-LCD) is to utilize the characteristic of liquid crystal molecule rotation polar biased light direction and birefraction to reach the effect that shows light and shade, this characteristic is relevant with the angle of incident light, therefore LCD just has the problem at visual angle in essence, along with audience's angle difference different display qualities is arranged, the visual angle big contrast of seeing of healing is lower, along with the development that LCD maximizes, promote each visual angle contrast and then more seem important with color homogeneity.

For the further application and the quality of expansion LCD, the research emphasis of current LCD, the reaction time that mainly concentrates on augmentation visual angle how and shorten screen.Desire to achieve the above object, prior art has been developed multiple wide viewing angle technology, for example transverse electric field handoff technique (In-PlaneSwitching; IPS), boundary electric field handoff technique (Fringe Field Switching; FFS) and multi-zone vertical alignment nematic technology (Multi-Domain Vertical Alignment; MVA).

But, above-mentioned wide viewing angle technology still is only limited to and is applied in penetration (transmissive) TFT-LCD.

Summary of the invention

A purpose of the present invention is to provide a kind of the have reflective Thin Film Transistor-LCD (reflective TFT-LCD) of locality (local) multi-zone vertical alignment nematic pattern (MVA) and the semi-penetration, semi-reflective Thin Film Transistor-LCD (transflectiveTFT-LCD) that has locality MVA pattern in the echo area.By make a plurality of interconnected conductive bumps point electrodes at reflecting plate, or/and form a corresponding electrode broken hole at each the prominent transparency electrode place of putting the upper substrate of apical position that corresponds to this reflecting plate, the liquid crystal that makes the echo area of this reflective TFT-LCD and this semi-penetration, semi-reflective TFT-LCD form the continuous multi-zone vertical alignment nematic pattern (continuous MVA) of a plurality of parts distributes, so that improve gray-scale inversion and colour cast problem, the augmentation visual angle.

The present invention discloses a kind of reflective Thin Film Transistor-LCD, comprise that one contains the transparent lower substrate of thin film transistor (TFT), be positioned at this transparent insulating layer above transparent lower substrate, wherein the upper surface of this transparent insulating layer has a plurality of prominent points (bumps), be made in a reflecting plate of the upper surface of this transparent insulating layer, wherein this reflecting plate has interconnected a plurality of (independently separate) conductive bumps point electrode that independently separates, when applying a voltage to this LCD, this each conductive bumps point electrode is used for the liquid crystal of the multi-zone vertical alignment nematic pattern that produces and distributes, one has the transparent upper of color filter layers, a transparent upper electrode and the liquid crystal layer between this transparent upper electrode and this reflecting plate at the color filter layers lower surface of this transparent upper.

In another embodiment of reflective Thin Film Transistor-LCD of the present invention, the upper surface of this transparent insulating layer has a plurality of first prominent point, and this reflecting plate has a plurality of second prominent point that corresponds to this a plurality of first prominent point, this a plurality of second prominent point wherein, and this transparent upper electrode is in the position that corresponds to this a plurality of second prominent point, has a corresponding broken hole, as the electrode breach, so that when applying a voltage to this LCD, the liquid crystal that makes this each second prominent point produce a multi-zone vertical alignment nematic pattern distributes.

Moreover the present invention also discloses a kind of semi-penetration, semi-reflective Thin Film Transistor-LCD, has an echo area and a penetrating region.This semi-penetration, semi-reflective Thin Film Transistor-LCD comprises that one contains the transparent lower substrate of thin film transistor (TFT), be positioned at this transparent insulating layer above transparent lower substrate of this echo area, wherein the upper surface of this transparent insulating layer has a plurality of prominent points (bumps), be made in a reflecting plate of the upper surface of this transparent insulating layer, wherein this reflecting plate has interconnected a plurality of (independently separate) conductive bumps point electrode that independently separates, when applying a voltage to this LCD, this each conductive bumps point electrode is used for the liquid crystal of the multi-zone vertical alignment nematic pattern that produces and distributes, be positioned at a top transparent bottom electrode of this transparent lower substrate of this penetrating region, wherein this transparent bottom electrode and this reflecting plate electrically connect, one has the transparent upper of color filter layers, a transparent upper electrode and the liquid crystal layer between this transparent upper electrode and this reflecting plate and this transparent upper electrode and this transparent bottom electrode at the color filter layers lower surface of this transparent upper.

In another embodiment of semi-penetration, semi-reflective Thin Film Transistor-LCD of the present invention, the upper surface of this transparent insulating layer has a plurality of first prominent point, and this reflecting plate has a plurality of second prominent point that corresponds to this a plurality of first prominent point, this a plurality of second prominent point wherein, and this transparent upper electrode is in the position that corresponds to this a plurality of second prominent point, has a corresponding broken hole, as the electrode breach, so that when applying a voltage to this LCD, the liquid crystal that makes this each second prominent point produce a multi-zone vertical alignment nematic pattern distributes.

Description of drawings

Fig. 1 has the structural profile synoptic diagram of conductive bumps point electrode in the echo area for semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element;

Fig. 2 has the vertical view of conductive bumps point electrode in the echo area for semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element;

Fig. 3 forms the analogous diagram that distributes of the copline multiple area arrangement of continuity of toppling over not for the oblique electric field of conductive bumps point electrode of the present invention liquid crystal molecule in making on every side;

Fig. 4 forms the section of structure of the embodiment 2 of local continuous multi-zone vertical alignment nematic pattern in the echo area for semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element;

Fig. 5 forms the vertical view of the embodiment 2 of local continuous multi-zone vertical alignment nematic pattern in the echo area for semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element;

Fig. 6 forms the vertical view of the embodiment 3 of local continuous multi-zone vertical alignment nematic pattern in the echo area for semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element; And

Fig. 7 forms the section of structure of the embodiment 3 of local continuous multi-zone vertical alignment nematic pattern in the echo area for semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element.

The figure number explanation

Reflecting plate 13 top glass substrate 20

Upper substrate transparency electrode 21 lower glass substrate 10

Conductive bumps point electrode 14 conductive bridge metals 18

Liquid crystal layer 25 penetrating region A

The prominent point 11,11 ' of echo area B

Broken hole 22 scanning linears 100

Signal wire 200 TFT 16

Storage capacitors 17 transparent electrode layers 12

The gap, electrode breach 15

Embodiment

But the invention provides the reflective LCD Structure of thin film transistor of vertical orientation at a kind of augmentation visual angle, but and in the structure at the augmentation visual angle, echo area of vertical orientation semi-penetration, semi-reflective Thin Film Transistor-LCD.Wherein, utilization makes the full wafer metallic reflection plate with a plurality of bump structures form many conductive bumps point electrodes that are connected to each other conducting (and outside these conductive bumps point electrodes, then as forming a non-conductive reticulate texture), or/and form a corresponding breach (hole) at the upper substrate transparency electrode place that corresponds to these prominent some apical positions, the liquid crystal layer that not only can make this reflective TFT-LCD or make the echo area of this semi-penetration, semi-reflective TFT-LCD like this, (i.e. a regional area) forms multi-zone vertical alignment nematic pattern (MVA) around every prominent point, and make LCD have more broad visual angle, and do not have influence on the main reflection light-guiding function of these prominent points.

Below be that example is described the present invention in detail with the structure of vertical orientation semi-penetration, semi-reflective TFT-LCD.

Embodiment 1

Fig. 1 is for showing the cross section structure that has the semi-penetration, semi-reflective TFT-LCD unit picture element of conductive bumps point electrode in the echo area of the present invention, wherein this LCD comprises the lower glass substrate 10 that is used for making TFT transistor (not shown), and the top glass substrate 20 that is used for making the colored filter (not shown).Have a liquid crystal layer 25 20,10 of upper and lower glass substrates,, and change the light angle of in penetrating region A and echo area B, passing through this liquid crystal layer 25 so that change the orientation and the arrangement mode of liquid crystal molecule according to the voltage that applies.One transparency electrode 21 (ITO electrode) be produced on top glass substrate 20 the color filter layers lower surface.Deposition one transparent electrode layer 12 (for example ITO layer) on the lower glass substrate 10 of penetrating region A is as the pixel electrode of penetrating region A.

Formation one has the transparent organic layer of a plurality of prominent points (bumps) 11 on the lower glass substrate 10 of echo area B, and afterwards, the metal level of deposition whole piece is as reflecting plate 13.And since this reflecting plate 13 be produced on this transparent organic layer with a plurality of prominent points 11, the surface of this reflecting plate 13 also have these bump structures 11 '.

Then, with the prominent point 11 of this full wafer metallic reflection plate 13 ' and prominent point 11 ' between most metal conducting layer of lowest part (spacing each other is about 3-5 μ m) etch away, form many conductive bumps point electrodes 14 with gap 15, and between prominent point and prominent some the bridge joint metal (bridge) 18 (being shown in Fig. 2) of some conductions of formation, so that make each conductive bumps point electrode 14 can be connected to each other conducting, as the pixel electrode of echo area B.Under preferable situation, 14 of each conductive bumps point electrodes contain two conductive bridge metals 18.

Fig. 2 has the vertical view of conductive bumps point electrode for demonstration semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element, wherein scanning linear 100 and signal wire 200 intersect vertically, in this unit picture element, have a switch module TFT16 and a storage capacitors 17, in the B of echo area, this reflecting plate 13 has the prominent point electrode 14 of plural conductive that is connected to each other conducting with conductive bridge metal 18.Lowest part (except the conductive bridge metal 18 that is connected) is organic dielectric layer of hollow out around each conductive bumps point electrode 14, just as forming slit, so liquid crystal molecule can be arranged along groove around each conductive bumps point electrode 14, makes each regional area all form the multi-zone vertical alignment nematic pattern.In fact, this conductive bumps point electrode arrangement 14 can cause strong oblique electric field, and the strong variation of equipotential line density, liquid crystal molecule generation in making around it is not coplanar to be toppled over, and cause the effect of local continuous multi-zone vertical alignment nematic pattern (continuous MVA), reach the purpose at augmentation visual angle.

Fig. 3 makes liquid crystal molecule in around each conductive bumps point electrode form the simulation result of the multiple area arrangement distribution of continuity toppled over of copline not for the oblique electric field of conductive bumps point electrode of the present invention.In the present embodiment, when applying voltage, gap 15 between two conductive bumps point electrodes 14, just form the electrode breach, as shown in Figure 3, the little but liquid crystal layer of the electric field of electrode indentation, there at interval (cell gap) bigger, and the electric field at conductive bumps point electrode 14 places is big but liquid crystal layer is less at interval, therefore make that the phasic difference value at two places can be close, and form the multiple zone of even brightness.

Embodiment 2

Please refer to Fig. 4 and Fig. 5, it shows that respectively semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element forms cross section structure and the vertical view of another embodiment of local continuous multi-zone vertical alignment nematic pattern in the echo area.

In the present embodiment, each prominent transparency electrode 21 place of putting the top glass substrate 20 of 11 ' apical position corresponding to this full wafer metallic reflection plate 13 form a corresponding broken hole 22, as the electrode breach.The shape of this broken hole 22 can be similar, for example circular or oval to this prominent point 11 ' shape.Certainly, leak to this liquid crystal layer 25 by this broken hole 22, can between this transparency electrode 21 and this colored filter (not shown), form a transparency protected tunic (not shown) for preventing the colorized optical filtering sheet material under top glass substrate 20.Thus, when applying voltage, the prominent point 11 ' on every side of each that also can be on this reflecting plate 13 forms the effect of the continuous multi-zone vertical alignment nematic pattern (continuous MVA) of a part.

Embodiment 3

Fig. 6 and Fig. 7, it shows that respectively semi-penetration, semi-reflective of the present invention TFT-LCD unit picture element forms cross section structure and the vertical view of the another embodiment of local continuous multi-zone vertical alignment nematic pattern in the echo area.Present embodiment is in conjunction with the embodiments 1 and the structure of embodiment 2, i.e. reflecting plate in the B of echo area 13, making is connected to each other the prominent point electrode 14 of plural conductive of conducting with conductive bridge metal 18, and at transparency electrode 21 places of the top glass substrate 20 that corresponds to prominent point electrode 14 apical positions of this plural conductive, form a corresponding electrode broken hole 22, as the electrode breach, form the effect of the continuous multi-zone vertical alignment nematic pattern of a part.

The above utilizes preferred embodiment to describe the present invention in detail, but not limits the scope of the invention, and know this type of skill personage and all can understand, suitably do slightly change and adjustment, will not lose main idea of the present invention place, also do not break away from the spirit and scope of the present invention.

Claims (10)

1, a kind of reflective Thin Film Transistor-LCD is characterized in that, comprising:

One contains the transparent lower substrate of thin film transistor (TFT);

One transparent insulating layer, it is positioned at this above transparent lower substrate, and the upper surface of this transparent insulating layer has a plurality of prominent points;

One reflecting plate, it is made in the upper surface of this transparent insulating layer, and have interconnected a plurality of conductive bumps point electrode that independently separates, wherein when applying a voltage to this LCD, this each conductive bumps point electrode is used for the liquid crystal of the multi-zone vertical alignment nematic pattern that produces and distributes;

One has the transparent upper of color filter layers;

One transparent upper electrode is positioned at the color filter layers lower surface of this transparent upper; And

One liquid crystal layer is between this transparent upper electrode and this reflecting plate.

2, reflective Thin Film Transistor-LCD as claimed in claim 1 is characterized in that, the prominent point electrode of this plural conductive is connected to each other with the conductive bridge metal, and these conductive bridge metal position lowest parts between two conductive bumps point electrodes.

3, reflective Thin Film Transistor-LCD as claimed in claim 1 is characterized in that, this transparent upper electrode has a corresponding electrode broken hole in the position that corresponds to this each conductive bumps point electrode top.

4, a kind of reflective Thin Film Transistor-LCD is characterized in that, comprising:

One contains the transparent lower substrate of thin film transistor (TFT);

One transparent insulating layer, it is positioned at this above transparent lower substrate, and the upper surface of this transparent insulating layer has a plurality of first prominent point;

One reflecting plate, it is made in the upper surface of this transparent insulating layer, and has a plurality of second prominent point, and wherein this a plurality of second prominent point corresponds to this a plurality of first prominent point;

One has the transparent upper of color filter layers;

One transparent upper electrode, be positioned at the color filter layers lower surface of this transparent upper, and this transparent upper electrode is in the position that corresponds to this a plurality of second prominent point, has a corresponding broken hole, as the electrode breach, so that when applying a voltage to this LCD, the liquid crystal that makes this each second prominent point produce a multi-zone vertical alignment nematic pattern distributes; And

One liquid crystal layer is between this transparent upper electrode and this reflecting plate.

5, reflective Thin Film Transistor-LCD as claimed in claim 4 is characterized in that, the broken hole of this transparent upper electrode is in the position that corresponds to this second prominent some top.

6, a kind of semi-penetration, semi-reflective Thin Film Transistor-LCD is characterized in that, divides into an echo area and a penetrating region and comprises:

One contains the transparent lower substrate of thin film transistor (TFT);

One transparent insulating layer, its be positioned at this echo area this above transparent lower substrate, and the upper surface of this transparent insulating layer has a plurality of prominent points;

One reflecting plate, it is made in the upper surface of this transparent insulating layer, and have interconnected a plurality of conductive bumps point electrode that independently separates, wherein when applying a voltage to this LCD, this each conductive bumps point electrode is used for the liquid crystal of the multi-zone vertical alignment nematic pattern that produces and distributes;

One transparent bottom electrode, its be positioned at this penetrating region this transparent lower substrate above, and electrically connect with this reflecting plate;

One has the transparent upper of color filter layers;

One transparent upper electrode is positioned at the color filter layers lower surface of this transparent upper; And

One liquid crystal layer is between this transparent upper electrode and this reflecting plate and this transparent upper electrode and this transparent bottom electrode.

7, semi-penetration, semi-reflective Thin Film Transistor-LCD as claimed in claim 6, it is characterized in that, the prominent point electrode of this plural conductive is connected to each other with the conductive bridge metal, and these conductive bridge metal position lowest parts between two conductive bumps point electrodes.

8, semi-penetration, semi-reflective Thin Film Transistor-LCD as claimed in claim 6 is characterized in that, this transparent upper electrode has a corresponding broken hole in the position that corresponds to this each conductive bumps point electrode top.

9, a kind of semi-penetration, semi-reflective Thin Film Transistor-LCD is characterized in that, divides into an echo area and a penetrating region and comprises:

One contains the transparent lower substrate of thin film transistor (TFT);

One transparent insulating layer, its be positioned at this echo area this transparent lower substrate above, and the upper surface of this transparent insulating layer has a plurality of first prominent point;

One reflecting plate, it is made in the upper surface of this transparent insulating layer, and has a plurality of second prominent point, and wherein this a plurality of second prominent point corresponds to this a plurality of first prominent point;

One transparent bottom electrode, its be positioned at this penetrating region this transparent lower substrate above, and electrically connect with this reflecting plate;

One has the transparent upper of color filter layers;

One transparent upper electrode, be positioned at the color filter layers lower surface of this transparent upper, and this transparent upper electrode is in the position that corresponds to this a plurality of second prominent point, has a corresponding broken hole, as the electrode breach, so that when applying a voltage to this LCD, the liquid crystal that makes this each second prominent point produce a multi-zone vertical alignment nematic pattern distributes; And

One liquid crystal layer is between this transparent upper electrode and this reflecting plate and this transparent upper electrode and this transparent bottom electrode.

10, semi-penetration, semi-reflective Thin Film Transistor-LCD as claimed in claim 9 is characterized in that, the broken hole of this transparent upper electrode is in the position that corresponds to this second prominent some top.

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