KR100670037B1 - Liquid crystal display - Google Patents

Abstract

The transmittance of each pixel is adjusted by changing the opening area of the red, green, and blue unit pixels. That is, the pixel having the lowest transmittance among the three color pixels of red, green, and blue has the maximum opening area, and the opening area of the other pixel is determined according to the difference in the transmittance of each pixel based on the pixel having the lowest transmittance. . Such a liquid crystal display may be implemented by forming a black matrix pattern to have a different opening area for each pixel. The opening area can be adjusted by changing only the length of the opening while keeping the width of the opening of the black matrix fixed.

Description

Liquid crystal display

The present invention relates to a liquid crystal display device.

In general, a liquid crystal display device has electrodes on both substrates or an inner surface of one substrate, and is an optical switching medium having a liquid crystal material layer between two electrodes. When a potential difference is applied to both electrodes, liquid crystal molecules are re-used due to the potential difference. Arranged and rearranged liquid crystal molecules scatter light or change light transmission properties. Polarizers are attached to the outer surfaces of the two substrates to adjust the amount of light passing through the polarizers to display an image.

As an example of a conventional liquid crystal display device, a nematic liquid crystal material is inserted between upper and lower electrodes formed on the inner surfaces of two lower and upper substrates, respectively, and the liquid crystal molecules are twisted and oriented parallel to the substrate. And a twisted nematic liquid crystal display disclosed in Patent No. 5,576,861. In this liquid crystal display, when a voltage is applied to the upper and lower electrodes to give a potential difference, an electric field perpendicular to both substrates is formed, and a torque for arranging the long axis direction of the liquid crystal molecules in parallel with the direction of the electric field (the magnitude of this torque is Depending on the strength of the electric field), ie, torque and rubbing due to the dielectric anisotropy, and the liquid crystal molecules are rearranged so as to balance the elastic torque for arranging the long axis direction of the liquid crystal molecules in a specific direction. At this time, the liquid crystal material between the two substrates is formed so that the twist direction of its major axis is changed by 90 degrees from one substrate to the other substrate, and the two polarizers are attached to the outer surfaces of the two substrates so that the transmission axes of the polarizers are perpendicular to each other. When the voltage is not applied to the two electrodes, the light passes through the liquid crystal layer and the polarization direction is changed to pass through most of the opposite polarizer to become a white state. When sufficient voltage is applied to the two electrodes, the polarizing plate is orthogonal. Light is blocked and goes to a black state.

Another example of a conventional liquid crystal display device is disclosed in US Pat. No. 5,598,285, in which two rows of electrodes are arranged in parallel on one substrate with a liquid crystal material layer between them, and the liquid crystal molecules are oriented parallel to the substrate. The liquid crystal display device (henceforth "plane drive type liquid crystal display device") is mentioned. In this liquid crystal display device, an electric potential is applied between electrodes to form an electric field essentially parallel to the substrate and perpendicular to the two electrodes, and the liquid crystal is balanced so that the torque due to the dielectric anisotropy of the liquid crystal material and the elastic torque due to the alignment treatment are balanced. The molecules rearrange. At this time, if the two polarizers are attached to the outer surfaces of the two substrates so that the transmission axes of the polarizers are perpendicular to each other, the light is blocked by the orthogonal polarizers when no voltage is applied to the two electrodes. When a sufficient voltage is applied to the two electrodes, light passes through the liquid crystal layer and the polarization direction is changed, and most of the light passes through the opposite polarizer to become a white state.

On the other hand, in order to display a color image with such a display device, a white light source is used, and the arrangement of liquid crystal molecules is changed to adjust the light transmission characteristics, and at the same time, a three-color filter of red, green, and blue light is used for additive mixing. Do it. To this end, red, green, and blue color filters are formed on one of two substrates of the liquid crystal display, and a black matrix is formed between the color filters to block leakage light.

However, as the light emitted from the light source passes through the liquid crystal layer, its characteristics are changed, so that a difference in transmittance between red, green, and blue pixels occurs for a unit pixel having the same opening. The difference in transmittance also depends on the driving method of the liquid crystal display.

1 to 2 show graphs of transmittance when the twisted nematic liquid crystal display and the planar drive type liquid crystal display according to the prior art are seen from the front.

As shown in FIG. 1, in the case of the twisted nematic liquid crystal display, the transmittance of the red and green filters is about 0.24 while no voltage is applied, whereas the transmittance of the blue filter is about 0.22 and about 10%. As shown in FIG. 2, when the voltage of 5 V is applied, the transmittance of the red filter is 0.15, the transmittance of the green filter is 0.13, and the transmittance of the blue filter is 0.8 as shown in FIG. 2. The difference is more than 40%.

In order to control such a difference in transmittance, the transmittance is corrected by using a backlight and a driving circuit having required characteristics for each device or by adjusting the heights of red, green, and blue color filters to vary cell spacing for each color. The method was mainly used. However, the use of different back light and driving circuits for each device results in an increase in cost or an increase in process. In addition, the method of adjusting the height of the color filter also leads to an increase in cost and process.

An object of the present invention is to make red, green, and blue pixel of a liquid crystal display device have the same transmittance.

In the liquid crystal display according to the present invention, the opening areas of the red, green, and blue pixels are different. That is, the aperture area of the pixel is determined based on one pixel among three color pixels of red, green, and blue, and based on the difference in transmittance for each pixel. Therefore, pixels with high transmittance have a relatively narrow opening area, and pixels with low transmittance have a relatively large opening area.

The opening area of the black matrix may be differently formed for each pixel to implement such a liquid crystal display. In order to change the opening area of the black matrix, the length of the opening may be varied while the width of the opening of the black matrix is fixed.

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

3 is a plan view of a black matrix according to an embodiment of the present invention. Such a black matrix may be formed on either of the two substrates above and below the liquid crystal display. The black matrix of FIG. 3 is applied to a twisted nematic liquid crystal display.

In FIG. 3, R, G, and B represent red, green, and blue pixels, respectively. When the transmittances of the red, green, and blue pixels are T _R , T _G , and T _B , and the opening areas of the red, green, and blue pixels are S _R , S _G , and S _B , respectively, T _R * S _R = T When _G * is S _G = T _B * is formed so that the opening area S _B. In FIG. 3, the openings of each pixel have a rectangular shape whose horizontal length is shorter than the vertical length. Since the horizontal length X of each opening is the same, the vertical lengths Y _R , Y _G , and Y _B of each opening are determined. You can adjust it.

As shown in FIG. 3, in the case of the blue pixel having the lowest transmittance, the black matrix is formed to have the maximum opening area. In the case of red and green pixels having a higher transmittance, the vertical length may be determined by a T _R * Y _R = T _G * Y _G = T _B * Y _B equation. In the twisted nematic liquid crystal display device, the red and green pixels exhibit almost the same transmittance, so that the vertical lengths Y _R and Y _G of the openings of the red and green pixels become (T _{B /} T _G ) * Y _B.

4 shows a pattern of a black matrix applied to a planar driving liquid crystal display as a second embodiment of the present invention.

In the case of the planar drive type liquid crystal display, the same equation as in the first embodiment of the present invention is applied.

In the case of the planar drive type liquid crystal display, the blue pixel shows the lowest transmittance, followed by the green pixel and the red pixel. As shown in FIG. 4, the blue pixel has the largest opening area and is formed such that the opening area gradually decreases in the order of the green pixel and the red pixel.

On the other hand, the method of adjusting the transmittance in this manner can be used in other types of liquid crystal display device in addition to the twisted nematic liquid crystal display device and the planar drive type liquid crystal display device. For example, the same may be applied to a PLS (plane to line switching) type liquid crystal display device. This will be described in detail below.

FIG. 5 is a diagram illustrating an arrangement of electrodes in a liquid crystal display according to a third exemplary embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along line VI-VI ′ of FIG. 5, showing both the upper substrate and the lower substrate. Electric field lines and equipotential lines are shown together.

First, the structure of the lower substrate in which an electrode is formed is demonstrated.

The planar electrode 2 is formed of a transparent conductive material such as indium tin oxide (ITO) on the inner surface of the lower substrate 10 made of a transparent insulating material such as glass or quartz, and has a long width in the horizontal direction. The insulating film 3 covers the planar electrode 2, and many stripe electrodes 1 which are narrow in width are formed in parallel with each other in the vertical direction. The stripe electrode 1 can be used as a transparent or opaque material, the width of which is smaller than the distance between the stripe electrodes 1, that is, the distance between adjacent border lines of two adjacent stripe electrodes 1. An alignment layer 30 made of a material such as polyimide is coated on the stripe electrode 1. On the other hand, a polarizing plate 20 is attached to the outer surface of the lower substrate 10.

An alignment layer 31 made of a material such as polyimide is formed on the inner surface of the substrate 11 made of a transparent insulating material such as glass or quartz, and a polarizing plate 21 is attached to the outer surface thereof.

Finally, a liquid crystal material layer having optical anisotropy is inserted between the alignment layers 30 and 31 of the two substrates 10 and 11.

The liquid crystal display device may perform a display operation by adjusting the transmittance of light from a backlight unit (not shown) positioned below the lower substrate 10, but may enter the upper portion of the upper substrate 11. The display operation may be performed using natural light, and in this case, the lower polarizer 20 is not necessary. In the case of a reflective liquid crystal display device using natural light, it is preferable to make both the striped electrode 1 and the planar electrode 2 made of a material having a high opacity and high reflectance, for example, aluminum (Al).

Next, the general shape of the electric field of the liquid crystal display will be described in detail with reference to FIG. 6.

When a voltage is applied to the two electrodes 1 and 2 to give a potential difference between the two electrodes 1 and 2, an electric field as shown in FIG. 6 is generated. The solid line in FIG. 6 represents an equipotential line, and the dotted line represents an electric force line.

As can be seen in FIG. 6, the shape of the electric field is a longitudinal center line C (actually a plane) of the narrow region NR above the striped electrode 1 and a wide area WR between the striped electrode 1. It is symmetric with respect to the longitudinal center line B (actually corresponding to the face). In the region from the centerline C of the narrow region NR to the centerline B of the large region WR, the vertex is at the boundary line A (actually a plane) between the narrow region NR and the large region WR. An electric field having an electric field line shape having a half ellipse shape or parabolic shape (hereinafter, referred to as a half ellipse shape for convenience) having a shape is generated. The tangent of the electric line of force is almost parallel to the substrate 10 on the boundary line A between the narrow region NR and the large region WR, and the substrate 10 at the central position of the narrow region NR and the large region WR. It is almost perpendicular to. In addition, the center and longitudinal vertices of the ellipse are located on the boundary line A between the narrow region NR and the wide region WR, and the two vertices of the horizontal direction are positioned in the large region WR and the narrow region NR, respectively. do. At this time, the horizontal vertex located in the narrow area NR has a shorter distance from the center of the ellipse than the horizontal vertex located in the wide area WR. Thus, the ellipse does not have symmetry with respect to the boundary line A. FIG. In addition, the density of electric field lines varies with position, and the strength of the electric field varies proportionally thereto. Thus, the intensity of the electric field is greatest on the boundary line AA between the narrow region NR and the large region WR, and toward the centerline CC, BB of the narrow region NR and the large region WR, and above. It becomes smaller toward the board | substrate 11.

Then, the state in which the liquid crystal molecules are rearranged by the electric field is divided into components that are horizontal to the substrate and components that are perpendicular thereto.

First, the initial state will be described.

The two alignment layers 30 and 31 are aligned by rubbing or ultraviolet irradiation, so that the liquid crystal molecules are all aligned in one direction, but have a slight pretilt angle with respect to the substrates 10 and 11 but are substantially horizontal. , 11) are arranged at a predetermined angle with respect to the direction of the striped electrode 1 and the direction perpendicular thereto. The polarization axes of the polarizing plates 20 and 21 are arranged to be orthogonal to each other, and the polarization axes of the lower polarizing plate 20 substantially coincide with the rubbing direction. The liquid crystal material contained between the two alignment layers 30 and 31 is a nematic liquid crystal having a positive dielectric anisotropy.

Next, a voltage is applied to the striped electrode 1 and the planar electrode 2, respectively, and a high voltage is applied to the striped electrode 1. At this time, the arrangement of the liquid crystal molecules is determined by equilibrium between the force due to the electric field (depending on the direction and intensity of the electric field) and the elastic restoring force generated by the alignment process.

The rearrangement state of the liquid crystal molecules is divided into components parallel to the substrate and perpendicular to the substrate. For convenience of explanation, the direction perpendicular to the substrate is z-axis, the direction perpendicular to the substrate and also perpendicular to the direction of the stripe electrode 1 is the x-axis, and the direction parallel to the direction of the stripe electrode 1 is taken as the y-axis. That is, the x-axis direction from left to right in FIG. 5, the y-axis direction from bottom to top along the stripe electrode 1, and the z-direction direction from the lower substrate 11 to the upper substrate 10 in FIG. 2. Let's grab the axis.

First, a change in the angle of the torsion angle of the liquid crystal molecules, that is, the plane of the long axis of the liquid crystal molecules with respect to the x-axis or the initial arrangement direction, that is, on the xy plane, will be described with reference to FIGS. 7, 8, and 9. do.

As shown in FIG. 7, the rubbing direction is represented by the vector vec R, the xy plane component of the electric field is represented by the vector {vec E} sub xy, and the optical axis of the lower polarizer 20 is represented by the vector vec P, and the rubbing direction is represented by x The angle formed by the axis is represented by ψ _R and the angle formed by the major axis of the liquid crystal molecule by the x axis is represented by ψ _LC . By the way, since the optical axis of the lower polarizing plate 20 coincides with the rubbing direction, the optical axis of the lower polarizing plate 20 is the angle ψ _P = ψ _R forming the x axis.

The direction of the xy plane component {vec E} sub xy of the electric field is in the positive x direction from the boundary line A to the center line B of the wide area WR, and the center line B of the wide area WR. From to the next boundary D in the negative x direction. The intensity of the electric field component is largest on the border lines A and D and becomes smaller toward the center line B-B and becomes zero on the center line B-B.

The magnitude of the elastic restoring force by the orientation treatment is constant regardless of the position on the xy plane.

Since the liquid crystal molecules should be arranged such that these two forces are in equilibrium, as shown in FIG. 8, in the boundary lines A and D, the long axis direction of the liquid crystal molecules is determined by the electric field component {vec E} sub xy. It is almost parallel to) and has a large angle with respect to the rubbing direction, but the angle along which the long axis of the liquid crystal molecules forms with respect to the rubbing direction (vert psi sub R-psi sub toward the center line (C, B) of the regions (NR, WR) LC vert) becomes smaller, and the major axis and the rubbing direction of the liquid crystal molecules become the same at the center lines B and C. Since the optical axis of the lower polarizing plate 20 is parallel to the rubbing direction, the angle formed between the optical axis of the lower polarizing plate 20 and the long axis of the liquid crystal molecules also has the same distribution, and this value is closely related to the transmittance of light.

By varying the ratio of the width of the narrow area NR to the wide area WR, various types of electric fields can be generated. When the stripe electrode 1 is used as an opaque electrode, the narrow area NR on the stripe electrode 1 cannot be used as the display area. However, when the stripe electrode 1 is made of a transparent material, the narrow area NR can also be used as the display area. .

Meanwhile, the xy plane component {vec E} sub xy of the electric field decreases gradually from the lower alignment layer 30 to the upper alignment layer 31, that is, along the z axis, and the elastic restoring force due to the alignment is obtained by the alignment layer 30. And 31, the largest on the surface, and gradually smaller toward the center of the liquid crystal layer between the two alignment films 30, 31.

9 shows a torsion angle at the position from the lower alignment layer 30 to the upper alignment layer 31, that is, along the z axis and in which the long axis direction of the liquid crystal molecules forms the x axis, as shown in FIG. 9. The case where the cell spacing is d is shown. Here, the horizontal axis means the height from the lower alignment layer 30, and the vertical axis indicates the twist angle.

9, it can be seen that the torsion angle is large because the force due to the alignment force is strong on the surfaces of the alignment layers 30 and 31, and becomes smaller toward the center of the liquid crystal layer, thereby becoming closer to the direction of the electric field. 31) Immediately above, the long axes of the liquid crystal molecules are arranged in the same direction as the rubbing direction. Here, when the difference in the twist angles of adjacent liquid crystal molecules is called twist, the twist in FIG. 9 corresponds to the slope of the curve, which is larger on the surfaces of the alignment layers 30 and 31 and smaller toward the center of the liquid crystal layer.

Next, referring to FIGS. 10, 11, and 12, the angle of inclination of the liquid crystal molecules, that is, the plane of the liquid crystal molecules perpendicular to the substrate with respect to the x-axis or the initial arrangement direction, for example, on the zx plane is described with reference to FIGS. Explain. In FIG. 10, only the substrates 10 and 11 are illustrated for convenience, and the component of the zx plane of the vector vec R representing the rubbing direction illustrated in FIG. 7 is a vector {vec R} sub zx, and the zx plane component of the electric field is a vector. {vec E} sub zx, and the angle of the zx plane component of the electric field {vec E} sub zx to the x-axis is θ _E , and the inclination angle of the long axis of the liquid crystal molecules to the x-axis is represented by θ _LC . By the way, since the vector vec R exists on the xy plane (ignore the pretilt angle), {vec R} sub zx becomes the x direction.

The magnitude of the zx plane component (vec E} sub zx) of the electric field is smaller as it goes from the lower substrate 10 to the upper substrate 11, and the angle θ _{E is} also smaller as it goes from the lower substrate 10 to the upper substrate 11. Lose.

As described above, the magnitude of the elastic restoring force due to the alignment treatment is the largest on the surfaces of the two substrates 10 and 11 and decreases toward the center of the liquid crystal layer.

The liquid crystal molecules must be arranged such that these two forces are in equilibrium. As shown in FIG. 11, since the alignment force is strong on the surface of the lower substrate 10, the liquid crystal molecules are arranged parallel to the x-axis, but as the upward force increases relative to the x-axis, the magnitude of the inclination angle θ _LC is increased. It continues to increase until the point, and then decreases again to be aligned parallel to the x-axis on the upper substrate 11 surface. At this time, the peak of the curve appears at a position close to the lower substrate 10.

On the other hand, the angle θ _E formed by the zx plane component (vec E} sub zx) of the electric field with respect to the x axis is closer to zero on the boundary lines A and D and becomes larger toward the center line BB, and the zx plane component of the electric field ({ vec E} sub zx) is the largest on boundaries A and D and decreases toward the center line BB.

The magnitude of the elastic restoring force by the orientation treatment is constant regardless of position on the x axis.

Accordingly, as shown in FIG. 12, the inclination angle of the liquid crystal molecules is almost zero at the boundary lines A and D, but increases toward the center lines C and B so that the zx plane component ({vec E} sub zx) of the electric field is x. It has a distribution similar to the angle θ _E with the axis. However, it changes more slowly than θ _E.

As such, when voltage is applied to the two electrodes 1 and 2, the liquid crystal molecules are rearranged at a torsion angle and an inclination angle, and the transmittance of light is changed due to a change in the torsion angle and the inclination angle. On the boundary lines A and D, there is little change in the inclination angle when viewed along the z axis, but the change in the torsion angle is large. On the other hand, on the center lines B and C, there is little change in the torsion angle when viewed along the z axis, but the inclination angle is slightly changed. Therefore, in the area between the boundary lines A and D and the center lines B and C, the torsion angle and the inclination angle are both changed. As a result, the transmittance curve according to the position becomes a shape similar to that of the electric field lines.

The PLS type liquid crystal display device formed as described above exhibits display characteristics similar to those of a flat drive type liquid crystal display device.

FIG. 13 is a graph illustrating a transmittance when the PLS type liquid crystal display is viewed from the front, and FIG. 14 is a plan view illustrating a black matrix applied to the PLS type liquid crystal display, which is a third embodiment of the present invention.

As shown in FIG. 13, when the voltage of 5 V is applied in the PLS type liquid crystal display, the transmittance of the red and green pixels is about 0.1%, and the blue pixels are about 20% higher. It has a low transmittance of about 0.08. Therefore, as shown in FIG. 14, the opening of the black matrix is formed to have the largest area in the blue pixel, and in the case of the red and green pixels, the vertical length is formed to be (T _{B /} T _G ) * Y _B. .

In the embodiment of the present invention, only the case in which the openings of the black matrix are formed in a long rectangular shape in the vertical direction has been described. The same effect as in the embodiment of the present invention can be obtained.

As in the embodiment of the present invention, the area of the opening of each pixel is formed differently according to the transmittance so that the red, green, and blue unit pixels may have the same transmittance, and thus, the same back light and the driving circuit may be different. It is applicable to the liquid crystal display device which has a drive system.

1 is a graph illustrating transmittances of red, green, and blue pixels of a twisted nematic liquid crystal display according to the related art.

FIG. 2 is a graph illustrating transmittances of red, green, and blue pixels of a planar driving liquid crystal display according to the related art.

3 is a plan view illustrating a black matrix of a twisted nematic liquid crystal display according to a first embodiment of the present invention;

4 is a plan view illustrating a black matrix of a planar driving liquid crystal display according to a second exemplary embodiment of the present invention.

5 is a layout view illustrating an electrode of a PLS type liquid crystal display according to a third exemplary embodiment of the present invention.

FIG. 6 is a cross-sectional view taken along line VI-VI ′ of FIG. 5, illustrating an equipotential line and an electric force line between the upper substrate, the lower substrate, and the two substrates.

7 is a view for explaining the change in the twist angle of the liquid crystal molecules in the third embodiment of the present invention,

FIG. 8 is a graph illustrating a change in the twist angle of liquid crystal molecules with respect to a line horizontal to a substrate and perpendicular to a striped electrode in a third embodiment of the present invention.

FIG. 9 is a graph showing a change in the twist angle of liquid crystal molecules with respect to the vertical line of the substrate in the third embodiment of the present invention.

10 is a view for explaining a change in the inclination angle of the liquid crystal molecules in the third embodiment of the present invention,

FIG. 11 is a graph showing a change in the twist angle of liquid crystal molecules with respect to the vertical line of the substrate in the third embodiment of the present invention.

12 is a graph illustrating a change in the inclination angle of liquid crystal molecules with respect to a line horizontal to the substrate and perpendicular to the striped electrode in the third embodiment of the present invention;

FIG. 13 is a graph illustrating transmittance for red, green, and blue pixels of a PLS type liquid crystal display according to a third exemplary embodiment of the present invention.

14 is a plan view illustrating a black matrix of a PLS type liquid crystal display according to a third exemplary embodiment of the present invention.

Claims (5)

First and second substrates facing each other, A planar electrode formed on the first substrate, A plurality of stripe electrodes formed on the first substrate by being insulated from the planar electrode and overlapping the planar electrode at least partially; One pixel includes at least one of the stripe electrodes and a planar electrode, and each pixel displays any one of red, green, and blue, and liquid crystals having different opening areas of the pixels displaying red, green, and blue. Display device. In claim 1, When the transmittances of the pixels displaying red, green, and blue are respectively T _R , T _G , and T _B , and the opening areas of the red, green, and blue pixels are S _R , S _G , and S _B , respectively, The aperture area of the red, green, and blue pixels satisfies the formula of T _R * S _R = T _G * S _G = T _B * S _B. First and second substrates facing each other, A planar electrode formed on the first substrate, A plurality of stripe electrodes formed on the first substrate by being insulated from the planar electrode and overlapping the planar electrode at least partially; One pixel includes at least one of the stripe electrodes and a planar electrode, and each pixel displays any one of red, green, and blue, and has an area of an opening exposing the red, green, and blue pixels. A liquid crystal display device comprising another black matrix. In claim 3, Transmittances of the pixels displaying red, green, and blue are respectively T _R , T _G , and T _B , and areas of openings exposing the red, green, and blue pixels of the black matrix are respectively S _R , S _G , When S _B , An area of the opening of the black matrix satisfies the formula of T _R * S _R = T _G * S _G = T _B * S _B. In claim 4, The openings of the black matrix are formed in a rectangle whose horizontal length is shorter than the vertical length, and the horizontal lengths of the openings exposing the red, green, and blue pixels are the same, and the vertical lengths of the openings are Y _R , Y _G , respectively. , Y _B , The opening of the black matrix is T _R * Y _R = T _G * Y _G = T _B * Y _B Liquid crystal display device satisfying the formula.