OCB mode LCD and method for driving the same

Disclosed is an OCB mode liquid crystal display and a method for driving the same. The OCB mode liquid crystal display includes at least one pair of upper and lower pre-tilt electrodes to partially cover each of upper and lower driving electrodes. A pre-tilt voltage equal to or higher than a transition voltage is applied between the upper and lower pre-tilt electrodes to shift liquid crystal molecules into a first orientation state, that is, to shift a portion of the liquid crystal molecules into a bend or vertical orientation state. Therefore, although a low driving voltage is applied between the upper and lower driving electrodes, the liquid crystal molecules can rapidly be shifted into a second orientation state for screen display. Consequently, a high response speed can be achieved, so that it is possible to display a high-speed moving picture and to reduce power consumption.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an OCB (Optically Compensated Bend) mode liquid crystal display and a driving method thereof, and more particularly to an OCB mode liquid crystal display which can rapidly shift the orientation state of liquid crystal molecules from an initial orientation state into an orientation state for screen display while consuming low power, and a method for driving the same.

2. Description of the Prior Art

As generally known in the art, liquid crystal displays are light, thin, short and small, are driven by a low voltage, and consumes a small power, so that the liquid crystal displays are now replacing cathode ray tubes (CRTs). Particularly, a thin-film transistor liquid crystal display has been a high-quality, a large size and colorization equal to those of the CRT, so that the thin-film transistor liquid crystal display is being variously utilized in many fields. Such a liquid crystal display includes an array substrate on which thin-film transistors and pixel electrodes are mounted, and a color-filter substrate on which a color filter and corresponding electrodes are mounted. The array substrate and the color-filter substrate are attached to each other with a liquid crystal layer interposed between the substrates. Generally, the liquid crystal display utilizes twisted-nematic (TN) mode liquid crystal.

A TN mode liquid crystal display has a high contrast in image display but has strong viewing-angle dependence. In order to solve such viewing-angle characteristic of the TN mode liquid crystal display, various methods including a pixel area division technique have been proposed. Also, to this end, an in-plane switching (IPS) mode liquid crystal display and a technique of forming a double domain in a liquid crystal layer have been proposed. Herein, the technique of forming a double domain in a liquid crystal layer includes a multiple rubbing method, a multiple orientation method, an edge fringe field method and a parallel fringe field method.

However, the conventional liquid crystal displays manufactured by the above-mentioned methods still have a problem in that they have a low response speed. That is, since the liquid crystal display utilizing the TN mode liquid crystal has a low response speed (the response speed between gradation displays is 100 ms in maximum), it is impossible to achieve 16.7 ms required to display a high-speed moving picture. Therefore, it has been required to develop a liquid crystal display having a wide viewing angle and a high response speed enough to display a high-speed moving picture. As a result, an OCB (Optically Compensated Bend) mode liquid crystal display has been proposed in order to improve a response speed and to obtain a uniform viewing-angle characteristic in all directions.

Hereinafter, the construction and the operation of a conventional OCB mode liquid crystal display will be schematically described with reference toFIGS. 1A to 1C.

The conventional OCB mode liquid crystal display contains: an upper substrate110including a color filter, an upper driving electrode140and an orientation layer; a lower substrate120including a TFT (Thin Film Transistor), an lower driving electrode150and an orientation layer; and liquid crystal molecules130interposed between the upper and lower substrates110and120. In this case, all the orientation layers included in the upper and lower substrates110and120are aligned in the same direction to each other. In the OCB mode liquid crystal display having such a construction, when a voltage is not applied between the upper and lower electrodes140and150, the liquid crystal molecules130are, as shown inFIG. 1A, maintained in a splay orientation state (which is an initial orientation state) according to the orientation processing direction of the orientation layers.

Meanwhile, when a pre-tilt voltage is applied between the upper and lower electrodes140and150, the liquid crystal molecules130are shifted from the splay orientation state into a bend orientation state as shown inFIG. 1B. In this case, the pre-tilt voltage must be higher than a transition voltage which is required for the liquid crystal molecules130to start a transition from the splay orientation state to the bend orientation state. A time period required for the liquid crystal molecules130to start a transition from the splay orientation state to the bend orientation state is called “transition time”. When a driving voltage is applied between the upper and lower electrodes140and150, the liquid crystal molecules130are shifted from the bend orientation state into a vertical orientation state by the driving voltage as shown inFIG. 1C, thereby linearly transmitting light. Thereafter, when there is no applied voltage, the liquid crystal molecules130are again shifted into the splay orientation state.

As described above, according to the conventional OCB mode liquid crystal display, the sate of the liquid crystal molecules130is repeatedly shifted in the sequence of the splay orientation state, the bend orientation state and the vertical orientation state by the voltage applied between the upper and lower electrodes140and150, thereby displaying an image. In this case, a pre-tilt voltage is first applied and then the driving voltage is applied so as to display an image.

However, such a conventional OCB mode liquid crystal display requires lots of power for the pre-tilt voltage to shift the liquid crystal molecules from the splay orientation state into the band orientation state, thereby increasing power consumption. Also, the conventional OCB mode liquid crystal display has problems in that the transition speed from the splay orientation state to the bend orientation state is slow (in fact, the transition between the two states is an unnecessary step in the process of displaying an image), its driving voltage is high, and it is difficult to achieve the bend orientation.

In order to solve such problems, there has been proposed a method for holding the liquid crystal molecules in a high pre-tilt state by mixing a monomer or a UV curing agent with liquid crystal molecules so as to easily achieve a transition to the bend orientation. As another method to solve the problems, Korean Patent Laid-Open Publication No. 2002-0097025 discloses a method for forming slant of a continuous saw-tooth shape on a cell surface so as to use the slant surface as a nucleus to shift liquid crystal molecules into the bend orientation state.

However, the former method has a problem in uniformity of display and the latter method has a difficulty in forming a slant surface on an ITO layer. Therefore, it is difficult to actually use either of the methods.

SUMMARY OF THE INVENTION

Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide an OCB mode liquid crystal display which can rapidly shift the orientation state of liquid crystal molecules from an initial orientation state into an orientation state for screen display while reducing power consumption, and a method for driving the same.

In order to accomplish this object, there is provided an OCB mode liquid crystal display comprising: upper and lower driving electrodes to which a driving voltage is applied, the upper and lower driving electrodes being provided at upper and lower substrates opposed to each other, respectively; a liquid crystal layer including a plurality of liquid crystal molecules interposed between the upper and lower substrates; and at least one pair of upper and lower pre-tilt electrodes to which a voltage to shift an orientation state of a portion of the liquid crystal molecules is applied, the upper and lower pre-tilt electrodes being located to partially cover each of the upper and lower driving electrodes.

In accordance with another aspect of the present invention, the pair of upper and lower pre-tilt electrodes are located in parallel to surfaces of the substrates, and are opposed to each other with the liquid crystal layer interposed between them in a direction perpendicular to the surfaces of the substrates.

In accordance with still another aspect of the present invention, there is provided an OCB mode liquid crystal display comprising: an array of upper and lower driving electrodes provided in upper and lower substrates, the upper and lower driving electrodes forming a pair, the upper and lower substrates being opposed to each other; a liquid crystal layer including a plurality of liquid crystal molecules interposed between the upper and lower substrates; and at least one pair of upper and lower pre-tilt electrodes corresponding to each pair of the upper and lower driving electrodes, the upper and lower pre-tilt electrodes being arranged to partially cover each of the upper and lower driving electrodes with an insulation layer interposed between the upper pre-tilt electrode and the upper driving electrode and with an insulation layer between the lower pre-tilt electrode and the lower driving electrode, upper and lower pre-tilt electrodes receiving a voltage to shift an orientation state of a portion of the liquid crystal molecules.

In accordance with still another aspect of the present invention, there is provided an OCB mode liquid crystal display comprising: a pair of substrates opposed to each other with a liquid crystal layer interposed between them; a common electrode formed on one of the substrates; a pixel electrode array to which a driving voltage is applied, the pixel electrode being formed on another of the substrates; and at least one pre-tilt electrode being arranged to partially cover each pixel electrode of the pixel electrode array, and receiving a pre-tilt voltage to shift an orientation state of a portion of liquid crystal molecules included in the liquid crystal layer.

In accordance with sill another aspect of the present invention, there is provided a method for driving an OCB mode liquid crystal display, the method comprising the steps of: arranging liquid crystal molecules into a first orientation state by applying the pre-tilt voltage to upper and lower substrates for each pixel, the liquid crystal molecules being oriented in partially different orientations in the first orientation state; and shifting the liquid crystal molecules from the first orientation state into a second orientation state for image display by applying the driving voltage to the upper and lower substrates, all the liquid crystal molecules being oriented in an equal direction for image display in the second orientation state.

In accordance with still another aspect of the present invention, the applied pre-tilt voltage has a higher level than that of the driving voltage for image display.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIGS. 2A to 2Dare views for explaining the construction and the operation of an OCB mode liquid crystal display according to an embodiment of the present invention.

The OCB mode liquid crystal display according to an embodiment of the present invention contains: an upper substrate210including a color filter, an upper driving electrode240and an orientation layer; a lower substrate220including a TFT (Thin Film Transistor), an lower driving electrode250and an orientation layer; and liquid crystal molecules230interposed between the upper and lower substrates210and220. Insulation layers260and261are formed on the upper and lower driving electrodes240and250of the upper and lower substrates210and220, respectively. Upper and lower pre-tilt electrodes270and280are formed on the insulation layers260and261, respectively, in such a manner that each pre-tilt electrode270or280extends in parallel to the surface of a corresponding substrate210or220so as to partially cover a corresponding driving electrode240or250. The upper and lower pre-tilt electrodes270and280are opposed to each other in the perpendicular direction to the surfaces of the substrates210and220, thereby forming a pair. Each of the upper and lower driving electrodes240and250has at least one pre-tilt electrode270or280. The orientation layers included in the upper and lower substrates210and220are aligned either in parallel or perpendicular to each other.

In the OCB mode liquid crystal display having the construction as described above, when no voltage is applied between the upper and lower driving electrodes240and250and between the upper and lower pre-tilt electrodes270and280, the liquid crystal molecules230are maintained in a splay orientation state (which is the initial orientation state) according to the aligned direction of the orientation layers as shown inFIG. 2A. In a state in which no voltage is applied between the upper and lower driving electrodes240and250, when a pre-tilt voltage equal to or higher than a transition voltage Vtris applied between the upper and lower pre-tilt electrodes270and280, the orientation state of the liquid crystal molecules positioned within the range between the upper and lower pre-tilt electrodes270and280is shifted from the initial orientation state into a first orientation state as shown inFIG. 2Bor2C.

To be specific, in the state in which no voltage is applied between the upper and lower driving electrodes240and250, when a first voltage is applied between the upper and lower pre-tilt electrodes270and280, the orientation state of the liquid crystal molecules positioned within the range between the upper and lower pre-tilt electrodes270and280is shifted from the splay orientation state into a bend orientation state as shown inFIG. 2B. Also, when a second voltage higher than the first voltage is applied between the upper and lower pre-tilt electrodes270and280, the orientation state of the liquid crystal molecules positioned within the range between the upper and lower pre-tilt electrodes270and280is shifted from the splay orientation state into a vertical orientation state as shown inFIG. 2C. In this case, the orientation state of liquid crystal molecules positioned adjacent to the range between the upper and lower pre-tilt electrodes270and280is also shifted from the splay orientation state into the bend orientation state, under the influence of the shifted orientation of the liquid crystal molecules positioned within the range between the upper and lower pre-tilt electrodes and an electric filed.

Thereafter, when a driving voltage is applied between the upper and lower driving electrodes240and250, all the liquid crystal molecules230are shifted from the fist orientation state into a second orientation state for screen display as shown inFIG. 2D, thereby linearly transmitting light.

According to the above-mentioned OCB mode liquid crystal display, with no driving voltage applied between the upper and lower driving electrodes240and250, a pre-tilt voltage equal to or higher than the transition voltage Vtris applied between the upper and lower pre-tilt electrodes270and280, so that the liquid crystal molecules positioned within the range between the upper and lower pre-tilt electrodes270and280are aligned in the bend orientation state or in the vertical orientation state. That is, liquid crystal molecules are partially aligned in the first orientation state.

As described above, according to the OCB mode liquid crystal display of an embodiment of the present invention, differently from the conventional OCB mode liquid crystal display, the upper and lower pre-tilt electrodes270and280are formed to partially cover the upper and lower driving electrodes240and250, respectively, so that it is possible to align the liquid crystal molecules in the first orientation state without exerting any effect upon screen display. As a result, although a driving voltage of a low level is applied between the upper and lower driving electrodes240and250, the liquid crystal molecules230can rapidly be shifted from the first orientation state into the second orientation state for screen display.

Hereinafter, the operation of the OCB mode liquid crystal display according to an embodiment of the present invention will be described with reference toFIGS. 3 and 4.

FIG. 3shows a graph illustrating light permeability according to driving voltages Vp applied between the upper and lower driving electrodes, in a state in which pre-tilt voltages Vsetof various levels are applied between upper and lower pre-tilt electrodes in a normal white type of OCB mode liquid crystal display.

To be specific,FIG. 3shows light permeability of the liquid crystal molecules according to driving voltages applied between the upper and lower driving electrodes, in a state in which each pre-tilt voltage of 0V310, 2V320, 4V330, 6V340and 8V350is applied between the upper and lower pre-tilt electrodes of the OCB mode liquid crystal display according to an embodiment of the present invention. Referring toFIG. 3, as the level of the pre-tilt voltage applied between the upper and lower pre-tilt electrodes rises higher, the magnitude of the transition voltage required to shift the orientation state of the liquid crystal molecules becomes lower, thereby also reducing the magnitude of the driving voltage Vp which is required to align all the liquid crystal molecules in the second orientation state. For reference, each driving voltage Vp corresponding to each inflection point in the graph becomes a transition voltage Vtr.

That is, the transition voltage Vtris 2.8V when the pre-tilt voltage Vsetis 0V, the transition voltage Vtris approximately 1.2V when the pre-tilt voltage Vsetis 4V, and the transition voltage Vtris approximately 0V when the pre-tilt voltage Vsetis 8V. Therefore, when the pre-tilt voltage Vsetof 0V is applied between the upper and lower pre-tilt electrodes of the OCB mode liquid crystal display having the above-mentioned construction, the initial orientation state of the liquid crystal molecules becomes the splay orientation state. In this case, a driving voltage Vp equal to or higher than 2.8V is applied between the upper and lower driving electrodes, the orientation state of the liquid crystal molecules starts to be shifted. Also, when the pre-tilt voltage Vsetof 4V is applied between the upper and lower pre-tilt electrodes, the transition voltage becomes approximately 1.2V. When the pre-tilt voltage Vsetof 8V is applied, the transition voltage becomes approximately 0V. In this case, when a driving voltage Vp equal to or higher than 0V is applied between the upper and lower driving electrodes, the orientation state of the liquid crystal molecules is shifted rapidly according to the magnitude of the driving voltage Vp.

Through such a procedure, the level of the pre-tilt voltage Vsetapplied between the upper and lower pre-tilt electrodes of the OCB mode liquid crystal display is established, and the first orientation state of the liquid crystal molecules is determined by the established pre-tilt voltage Vset.

FIG. 4is a waveform diagram illustrating the operation of the OCB mode liquid crystal display which has been established to apply a pre-tilt voltage Vsetof a predetermined level to the upper and lower pre-tilt electrodes through the above-mentioned procedure.

As shown inFIG. 4, a pre-tilt voltage Vsetequal to or higher than the transition voltage Vtris applied between the upper and lower pre-tilt electrodes of the OCB mode liquid crystal display. Such a pre-tilt voltage Vsetshifts a portion of the liquid crystal molecules from an initial orientation state into the first orientation state, that is, to the bend orientation state or to the vertical orientation state. In addition, in the OCB mode liquid crystal display, the gate voltage Vg of a predetermined level is periodically applied, and the pre-tilt voltage Vsetis applied with its polarity repeatedly inverted at the same period as that of the gate voltage Vg.

In this case, the gate voltage Vg is applied to a gate electrode connected a gate line to be displayed, thereby turning on a corresponding thin-film transistor, and a data voltage expressing an image signal is applied to the source electrode thereof so that the applied data voltage may be outputted through the drain electrode thereof. Then, the data voltage outputted through the drain electrode is applied to one driving electrode (pixel electrode) as a driving voltage (or a pixel voltage; Vp). The pixel voltage Vp applied the pixel electrode and a common voltage Vcom applied to another driving electrode (common electrode) corresponding to the pixel voltage forms an electric field by a potential difference between the voltages. The potential difference is applied to liquid crystal molecules interposed between a pair of driving electrodes to align the liquid crystal molecules in the second orientation state, thereby transmitting light to obtain an image. The pixel voltage Vp is charged during a period in which the gate voltage Vg is applied, and is maintained at a predetermined level during a period in which the gate voltage Vg is not applied.

Thereafter, when the gate voltage Vg is again applied, the thin-film transistor is turned on, the pixel voltage Vp is applied to the pixel electrode and is charged. In this case, the pre-tilt voltage Vsetand the pixel voltage Vp have polarities reversed from those of the previous frame, and the pre-tilt voltage Vsethas a higher voltage level than the pixel voltage Vp. Meanwhile, when the gate voltage Vg is not applied, the thin-film transistor is turned off, and the pixel voltage Vp is maintained at a predetermined level. By the electric field between the pixel voltage Vp applied the pixel electrode and the common voltage Vcom applied to the common electrode, a potential difference is formed. Such a potential difference is applied to liquid crystal molecules interposed between a pair of driving electrodes to align the liquid crystal molecules in the second orientation state, thereby transmitting light to obtain an image.

Consequently, while the gate voltage Vg and the pre-tilt voltage Vsetare periodically applied to the OCB mode liquid crystal display, the pixel voltage Vp is applied, thereby obtaining continuous images.

As described above, the OCB mode liquid crystal display according to an embodiment of the present invention includes at least one pair of pre-tilt electrodes, which are arranged to partially cover each of the upper and lower driving electrodes of the upper and lower substrates. A pre-tilt voltage equal to or higher than the transition voltage is applied between the pre-tilt electrodes to shift a portion of liquid crystal molecules into the first orientation state. Thereafter, when a driving voltage is applied between the upper and lower driving electrodes, the liquid crystal molecules rapidly are shifted from the first orientation state into the second orientation state. In this case, although a low driving voltage is applied between the upper and lower driving electrodes, the liquid crystal molecules can be shifted into the second orientation state. As a result, the OCB mode liquid crystal display according to an embodiment of the present invention has a high response speed and can be driven with low power.

Although the embodiments of the present invention has been illustrated and described with respect to only a pair of driving electrodes included between the upper and lower substrates, those skilled in the art will appreciate that a pair of driving electrodes corresponds to one pixel, and thus many pairs of driving electrodes (i.e., array of pairs of driving electrodes) are formed in the upper and lower substrates.

As described above, according to an embodiment of the present invention, the OCB mode liquid crystal display includes at least one pair of upper and lower pre-tilt electrodes to partially cover each of the upper and lower driving electrodes. A pre-tilt voltage equal to or higher than the transition voltage is applied between the upper and lower pre-tilt electrodes to shift the orientation state of the liquid crystal molecules into the first orientation state, that is, to shift the orientation state of the liquid crystal molecules into the bend or vertical orientation state. As a result, although a low driving voltage is applied between the upper and lower driving electrodes, the liquid crystal molecules can rapidly be shifted into the second orientation state for screen display. Consequently, the OCB mode liquid crystal display according to an embodiment of the present invention can achieve a high response speed, so that it is possible to display a high-speed moving picture and to reduce power consumption because it can operate with low power.