KR100209604B1 - Position detect lcd device - Google Patents

Abstract

The present invention relates to a position detection liquid crystal display device, which prevents the distortion of the potential distribution by preventing the coupling phenomenon between the ITO layer for the common electrode and the compensation resistor layer for compensating the distortion of the driving signal, thereby enabling accurate position detection. It is to provide a detection liquid crystal display device.

The position detection liquid crystal display device of the present invention is a position detection device using a black matrix as a grid, the equipotential holding formed on a substrate having a position detection area consisting of a plurality of grid array, the substrate around the position detection area And a first ITO layer formed on the resistance and equipotential compensation resistor, the first ITO layer formed on the position detection region, the second ITO layer formed on the equipotential sustaining resistance of the portion in contact with the equipotential compensation resistor.

Description

Position detection liquid crystal display device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a position sensing liquid crystal display (PSLCD), and more particularly, to a capacitive coupling between a common electrode and a black matrix in a position detecting liquid crystal display device using a black matrix as a position detecting device. The present invention relates to a position detection liquid crystal display device capable of accurate position detection by preventing capacitive coupling.

Hereinafter, a conventional position detection liquid crystal display device will be described with reference to the accompanying drawings.

FIG. 1A shows the X-axis grid and the Y-axis grid of the position detection device, and FIG. 1B shows the voltage distribution when a drive signal is applied to such a position detection device.

First, as shown in FIG. 1A, when driving signals are applied at four corners 1, 2, 3, and 4 of the position detecting apparatus, X, Y is used to determine the exact position of the electronic pen (or stylus). The voltage should be linearly distributed on the axis grids 11, 12.

However, as shown in FIG. 1B, the voltage distribution in the first X-direction grid is not linear and appears nonlinear as shown by reference numeral A. FIG.

That is, a non-active area is generated that cannot detect the position of the stylus by a on the X axis and b on the Y axis.

Therefore, the actual position detection area in the position detection device is a reference numeral or area as shown in FIG. 1B.

Also, the nonlinear potential distribution in the first X-direction grid makes the potential distribution in the next X-direction grid also non-linear, so the exact position of the stylus due to the non-linear potential distribution within the position detection area. Difficult to detect

In order to solve the above problems, a nonlinear voltage distribution was compensated for by using an equipotentializing resistor and an equipotential holding resistor in addition to the grid (mesh resistor).

2 shows a part of the position detection device using such an equipotential compensation resistor and an equipotential holding resistor.

In the conventional position detection device, a plurality of equipotential compensation resistors 23 are connected to the X and Y axis grids 21 and 22 connected in the vertical and horizontal directions so as to extend in corresponding directions (data line and scan line directions). Each equipotential compensation resistor 23 in the same direction is connected to one equipotential sustaining resistor 24 (in FIG. 2, only the equipotential sustaining resistor and the equipotential compensating resistor in the horizontal direction are shown).

Here, the X- and Y-axis grids 21 and 22 are formed of a black matrix layer, and the grids are not connected to each other up, down, left, and right for each pixel, and cross the plurality of pixels to cross the grids 21 and 22 of the X and Y axes. Are connected to each other.

In this case, as described above, the X-axis grid 21 and the Y-axis grid 22 are formed to correspond to each of the n gate lines and the m data lines one by one, and are formed wider than the gap between the gate lines and the data lines.

Accordingly, driving signals for detecting positions of the stylus in the X-axis direction and the Y-axis direction are applied through the X-axis and Y-axis grids 21 and 22.

The equipotential holding resistors 24 are formed over the top, bottom, left, and right sides of the display device, and the respective equipotential holding resistors 24 extend to drive driving AC signals to corner portions (four corner portions of the top plate) where they meet neighboring equipotential holding resistors. A drive signal applying unit (not shown) for application is formed.

The driving signal applying unit and each equipotential holding resistor 24 are connected by a plurality of node resistors (not shown).

This will be described in detail as follows.

Each equipotential compensation resistor 23 connected to the same equipotential holding resistor 24 should have a lower resistance value as it moves away from the driving signal applying unit, so that each equipotential compensation resistor 23 has a different resistance value.

As shown in FIG. 2, the width of the equipotential compensation resistor 23 increases in proportion to the distance from the edge where the driving signal is applied.

Although not shown in FIG. 2, the driving signal applying unit is formed near four vertices of the image.

In this case, the driving signal for detecting the position is not directly supplied to the upper plate, but is supplied through the lower plate, so that the thin film transistor and the pixel electrode are arranged on the lower plate, and a signal line for applying the driving signal is configured separately.

Therefore, the driving signal applying unit serves to connect the driving signal applied through the signal line to the top plate.

Here, the potential applied at the same position in the vertical or horizontal direction of the portion where the equipotential compensation resistor and the grid are connected by the equipotential holding resistor and the equipotential compensation resistor is the same.

In other words, the potential distribution of the driving signals applied to the X-axis and Y-axis grids 21, 22 is equalized using the equipotential sustaining resistor 24, the equipotential compensating resistor 23, and the node resistor.

Therefore, we wanted to maximize the active area of the stylus.

3 is a cross-sectional view of a position detection apparatus according to the prior art.

As shown in FIG. 3, a portion except for the data line and the scan line disposed on the matrix, the thin film transistor disposed at each intersection point, and the lower plate 31 on which the pixel electrode is formed, and the pixel electrode formed on the lower plate 31, are excluded. In order to block the light incident to the black matrix layer 32a formed at a predetermined interval, the R, G, B color filter layer 32b formed between each of the black matrix layer 32a to express a color, the color filter layer ( 32b) and an upper plate 32 including an overcoat layer 32c formed over the black matrix layer 32b, an ITO layer 32d for the common electrode formed on the overcoat layer 32c, and the lower plate ( And liquid crystal 33 encapsulated between the upper plate 31 and the upper plate 32.

Here, the equipotential compensation resistor 34 is connected to the black matrix layer 32a, and the equipotential sustaining resistor 35 is connected to the equipotential compensation resistor 34.

Conventionally, even if the equipotential sustaining resistor 35 and the equipotential compensating resistor 34 are configured for each grid for the equipotential, the ITO layer 32d for the common electrode is covered up to the equipotential sustaining resistor 35 and the equipotential compensating resistor 34. Therefore, as shown in FIG. 3, crosstalk due to capacitive coupling occurs.

That is, the ITO layer 32d, the equipotential sustaining resistor 35 and the equipotential compensating resistor 34, and the black matrix layer 32a each have a conductor on both sides of a dielectric (overcoat layer), so that capacitance is present. When the AC voltage is applied to the equipotential sustaining resistor 35, the compensation resistor 34, and the black matrix layer 32a, the AC voltage is induced to the ITO 32d through the parasitic capacitor.

The Vpp of the AC voltage induced in the ITO 32d is about 1/2 of the Vpp input to the initial driving signal applying unit, and this magnitude is almost equal to the voltage at the center point of the black matrix layer 32a. As shown in FIG. 1B, dislocation distortions in the form of symmetry up and down occur.

In this phenomenon, as shown in FIG. 2, not only the distorted signal is applied to the grid to which the driving signal is initially applied but also the signal detected by the stylus is very small.

4 shows a capacitive coupling in case of position detection using an electronic pen or stylus according to the prior art.

As shown in FIG. 4, when the stylus 41 or the electronic pen approaches the surface of the position detection device for position detection, the coupling (reference numeral C) and the common electrode for grid electrode made of a black matrix 32a are used. Coupling (reference numeral D) occurs by the ITO layer 32d.

The conventional position detection liquid crystal display device as described above has the following problems.

Since the driving signal is an AC signal, signal distortion occurs at the point where the driving signal is applied due to the coupling phenomenon between the equipotential sustaining resistor, the equipotential compensating resistor, the grid resistor, and the ITO for the common electrode.

Therefore, since the distortion of the signal generated at the input point of the drive signal causes voltage distortion distributed on the grid resistor (black matrix), accurate position detection by the stylus is difficult.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a position detection liquid crystal display device capable of accurate position detection by minimizing the coupling phenomenon caused by the ITO layer by eliminating unnecessary ITO and thereby preventing signal distortion. There is a purpose.

1A is a view showing X and Y grids of a general position detection device.

FIG. 1b is a potential distribution when voltage is applied to the X and Y grids of FIG.

2 is a plan view of a top plate according to a conventional position detection liquid crystal display device.

3 is a cross-sectional view of a conventional position detection liquid crystal display device.

4 is a view illustrating a coupling phenomenon that occurs when detecting a position using a conventional position detection liquid crystal display device.

5 is a conceptual diagram of a top plate for explaining the position detection liquid crystal display device of the present invention.

6 is a plan view of a top plate according to the first embodiment of the position detection liquid crystal display device of the present invention.

7 is a plan view of a top plate according to a second embodiment of a position detection liquid crystal display device of the present invention.

8 is a plan view of a top plate according to a third embodiment of a position detection liquid crystal display device of the present invention.

9 is a plan view of a top plate according to a fourth embodiment of the position detection liquid crystal display device of the present invention.

* Explanation of symbols for main parts of the drawings

51,64: active area 52: compensation resistance area

53: ITO layer 61,71: top glass

63, 73: equipotential holding resistor 72: driving signal applying unit

75a: X axis grid 75b: Y axis grid

76,77: 1st, 2nd ITO layer

A position detection liquid crystal display device of the present invention for achieving the above object is a position detection device using a black matrix as a grid, the substrate having a position detection area consisting of a plurality of grid array, the substrate around the position detection area And a second ITO layer formed on the equipotential holding resistance formed on the first potential layer, the first ITO layer formed on the position detecting region, the equipotential compensating resistor, and the equipotential holding resistor in a portion in contact with the equipotential compensating resistance. do.

Hereinafter, the position detection liquid crystal display device of the present invention will be described with reference to the accompanying drawings.

5 is a plan view of a top plate for explaining the position detection liquid crystal display device of the present invention.

As shown in FIG. 5, the ITO layer 53 is not formed in the compensation resistance region (equipotential compensation resistor, equipotential sustaining resistor) 52 other than the active region 51.

Since the ITO layer 53 is necessary in the active region 51 as the counter electrode of the pixel electrode, the ITO layer 53 of the grid resistance portion (active region) remains the same and does not play a role in the liquid crystal display device. ITO layers other than (51) are removed.

Therefore, the driving signal for position detection is input to the grid resistor without any distortion.

Such a position detection liquid crystal display device of the present invention will be described in more detail as follows.

6 shows a first embodiment of the position detection liquid crystal display device of the present invention.

As shown in FIG. 6, the first embodiment of the present invention forms an ITO layer only on an active region of an LCD.

That is, the first regions 62 are formed near four corners of the upper plate glass 61 to apply a driving signal to the grid resistor, and are connected to each other between the first regions 61 to compensate for the potential difference. An active region 64 made up of an equipotential holding resistor 63, an ITO layer formed inside the equipotential holding resistor 63, and grid resistors for position detection; And equipotential compensation resistors 65 connected to the grid resistor at regular intervals between the equipotential holding resistors 63.

In the glass 61 outside the equipotential sustaining resistor 63, second regions 66 are formed to apply Vcom to the ITO layer at a predetermined interval.

In this case, an ITO layer is formed on the second region 66, and the ITO layer is connected to the ITO layer formed on the sham active region 64.

Such a position extraction liquid crystal display device does not form an ITO layer on the compensation resistance region (the equipotential compensation resistor 65 region and the equipotential holding resistor 63 region) as shown in FIG. The ITO layer is formed only in the portion (second region) for applying the Vcom signal to the ITO layer formed in the.

Therefore, since the interference between the ITO layer and the resistance element does not occur at the input terminal of the grid resistance region via the compensation resistor region, input of an undistorted signal is possible.

It also prevents the signal from becoming smaller due to interference by the ITO layer.

7 is a plan view of the upper plate according to the second embodiment of the position detection liquid crystal display device of the present invention.

According to the second embodiment of the present invention, first, the driving signal applying unit 72 formed near the edge of the upper plate glass 71 and the driving signal applying unit 72 are formed in the X-axis direction and the Y-axis direction, respectively. An equipotential sustaining resistor 73, an equipotential compensating resistor 74 connected to the equipotential sustaining resistor 73 and formed at a predetermined interval from each other, an X-axis grid 75a connected to the equipotential sustaining resistor 73, and The equipotential compensation resistor including a grid resistance region 75 including a Y-axis grid 75b, a first ITO layer 76 formed on the grid resistance region 75, and the equipotential compensation resistor 74. The second ITO layer 77 has a predetermined width and is formed in a T shape on the equipotential holding resistor 73 of the portion in contact with 74).

In this case, since the grid resistance region 75 has the same region as the active region of the LCD, the region of the ITO layer coincides with the active region.

The area of the second ITO layer 77 is wider than the equipotential sustaining resistor 73 or the equipotential compensating resistor 74.

In addition, the first ITO layer 76 and the second ITO layer 77 are formed to be separated from each other.

As such, when the first ITO layer 76 and the second ITO layer 77 are separated from each other, distortion of the potential distribution due to the coupling between the black matrix layer used as the grid and the second ITO layer 77 is prevented.

In other words, the T-shaped second ITO layer 77 is formed for each equipotential sustaining resistor 73 and equipotential compensating resistor 74.

However, since the first ITO layer 76 and the respective T-shaped ITO layers 76 and 77 are also separated, the equipotential holding resistor 73 and the equipotential compensating resistor 74 and the second ITO layer 77 are separated. The distortion of the voltage due to the coupling with does not occur.

Therefore, the first grid to which the drive signal is input is equipotential.

8 is a plan view of the upper plate according to the third embodiment of the position detection liquid crystal display device of the present invention.

The third embodiment of the present invention is a quadrangle of the second ITO layer 77 formed on the equipotential compensation resistor 74 and the equipotential holding resistor 73 in contact with the equipotential compensation resistor 74 described in the second embodiment. Pattern in the form of.

Such a third embodiment of the present invention can more easily pattern the second ITO layer 77 with the effects described in the second embodiment.

9 is a plan view of the top plate according to the fourth embodiment of the position detection liquid crystal display device of the present invention.

First, the fourth embodiment of the present invention is integrally formed without separating the first ITO layer 76 formed on the active region and the second ITO layer 77 on the upper side of the equipotential sustaining resistor in contact with the equipotential compensating resistor and the equipotential compensating resistor. do.

That is, as shown in FIG. 9, the driving signal applying unit 72 formed near the edge of the upper plate glass 71 and the driving signal applying unit 72 are formed in the X-axis direction and the Y-axis direction, respectively. An equipotential sustaining resistor 73, an equipotential compensating resistor 74 connected to the equipotential sustaining resistor 73 and formed at a predetermined interval from each other, an X-axis grid 75a connected to the equipotential sustaining resistor 74, and Equipotential holding resistance of the portion which is in contact with the equipotential compensation resistor 74, including the grid resistance region 75 formed with the Y-axis grid 75b, and the grid resistance region 75 and the equipotential compensation resistor 74 73) and ITO layers 76 and 76a formed with a predetermined width.

According to the fourth embodiment of the present invention, the effect is excellent in shielding the signals transmitted from the source IC and the gate IC.

As described above, the position detection liquid crystal display device of the present invention has the following effects.

First, the coupling phenomenon is prevented by removing unnecessary portions of the ITO formed outside the active region, thereby preventing distortion of the voltage due to the coupling.

Second, the ITO layer on the active region and the ITO layer on the compensating resistor (equipotential compensating resistor, equipotential holding resistor) are separated from each other to improve the shielding effect from the signal transmitted from the source and gate IC.

Claims (9)

In a position detection device using a black matrix for each grid, an equipotential compensation is provided in the position detection area formed by arranging the grids in the X-axis and Y-axis directions, and the periphery of the position detection area to compensate for the distortion of the driving signal. And an ITO layer formed only on the position detecting region. The position detection liquid crystal display device of claim 1, wherein an area of the ITO layer is patterned to be wider than a compensation resistance. A position detection apparatus using a black matrix as a grid, the position detection apparatus comprising: a substrate having a position detection region composed of a plurality of grids; an equipotential holding resistance and an equipotential compensation resistance formed on a substrate around the position detection region; And a second ITO layer formed on the first ITO layer formed on the first ITO layer, the equipotential compensating resistor and the equipotential holding resistor in a portion in contact with the equipotential compensating resistor, and separated from the first ITO layer. 4. The position detection liquid crystal display device according to claim 3, wherein an area of the second ITO layer is wider than the equipotential holding resistance and the equipotential compensation resistance. 4. The position detection liquid crystal display device according to claim 3, wherein the second ITO layer is floated with each other for each grid. The liquid crystal display device of claim 3, wherein the first ITO layer and the second ITO layer are integrally patterned with each other. The liquid crystal display device of claim 3, wherein the first ITO layer and the second ITO layer are patterned to be separated from each other. The liquid crystal display device of claim 3, wherein the second ITO layer is patterned in a T shape. The liquid crystal display of claim 3, wherein the second ITO layer is patterned in a rectangular shape.