KR102468288B1 - Touch Display Device - Google Patents

Abstract

The present invention provides a touch panel including a plurality of touch electrodes having different areas, a touch scan signal is applied to the plurality of touch electrodes, and a change in capacitance of the plurality of touch electrodes is analyzed to detect the position of a touch input. To provide a touch display device including a touch driver that applies the touch scan signal to the plurality of touch electrodes, respectively, and a plurality of signal applying paths each having a resistance inversely proportional to the area of the plurality of touch electrodes. By making the signal applying path including the touch wiring have different resistances according to the capacitance of the electrode, errors in touch operation and display operation are prevented and accuracy and uniformity are improved.

Description

Touch Display Device {Touch Display Device}

The present invention relates to a touch display device, and more particularly, to a touch display device in which errors in a touch operation and a display operation due to a difference in area of touch electrodes are prevented.

In line with the information age, the display field has also developed rapidly, and in response to this, a liquid crystal display device (LCD) as a flat panel display device (FPD) has advantages of thinning, lightening, and low power consumption. ), plasma display panel device (PDP), organic light emitting diode display device (OLED), field emission display device (FED), etc. It is rapidly replacing the cathode ray tube (CRT).

Recently, a touch display device (or touch screen) in which a touch panel is attached on such a display panel has been in the spotlight.

The touch display device is used as an output means for displaying an image, and at the same time used as an input means for receiving a user's command by touching a specific part of the displayed image. It can be divided into a method, an infrared method, an ultrasonic method, and the like.

That is, when a user touches the touch panel while viewing an image displayed on the display panel, the touch panel detects the location information of the corresponding part and compares the detected location information with the location information of the image to recognize the user's command.

The touch display device can be manufactured in the form of attaching a separate touch panel to the display panel. In recent years, in particular, electrodes and wiring constituting the touch panel are applied to the substrate of the display panel to slim down portable terminals such as smart phones and tablet PCs. Demand for an in-cell type touch display device in which the touch display device is formed and integrated is increasing.

This in-cell type touch display device will be described with reference to the drawings.

FIG. 1 is a diagram showing a conventional in-cell type touch display device, particularly a self-capacitance type in-cell type touch display device.

As shown in FIG. 1 , a conventional self-capacitance type in-cell touch display device 10 includes a touch panel 20 and a touch driver 30 .

The touch panel 20 includes a plurality of touch electrodes 22 and a plurality of touch wires 24 connecting the plurality of touch electrodes 22 and the touch driver 30, respectively. ) each have a rectangular shape.

The touch driver 30 applies a touch scan signal to the plurality of touch electrodes 22 of the touch panel 20 and analyzes the change in capacitance of the plurality of touch electrodes 22 according to the applied touch scan signal. The position of the touch input of the touch panel 20 is sensed.

In the in-cell type touch display device 10 of the self-capacitance type, the area of each of the plurality of touch electrodes 22 is reduced and the number of the plurality of touch wires 24 is increased so that the accuracy of the position of the touch input, that is, Resolution can be improved.

However, since the touch panel 20 is also used as a display panel, there is a limit to reducing the area of each of the plurality of touch electrodes 22 and increasing the number of the plurality of touch wires 24. Accordingly, the touch accuracy and There is a problem with the resolution being lowered.

For example, two points (A, B) spaced apart in a diagonal direction within one touch electrode 22 are separated by a relatively long distance, but are detected as one position by the touch driver 30, so the touch operation An error occurs, and the touch accuracy and resolution are degraded.

Meanwhile, each of the plurality of touch electrodes 22 is connected to the plurality of touch wires 24 through the contact point CP. As shown in FIG. 1, the leftmost side of one vertical column of the plurality of touch electrodes 22 The touch wire 24 of is connected to the uppermost touch electrode 22, the rightmost touch wire 24 is connected to the lowermost touch electrode 22, and the touch wire 24 goes from left to right between them. When connected to the lower touch electrode 22, there is a problem in that a difference in luminance occurs due to a difference in resistance at the boundary between adjacent touch electrodes 22.

For example, since the first and second touch electrodes 22a and 22b are connected to the first and second touch wires 24a and 24b through the left contact point CP, the first touch electrode 22a The point C of the right boundary of is located at a relatively far distance from the contact point CP, and the point D of the left boundary of the second touch electrode 22b is located at a relatively short distance from the contact point CP. As a result, the resistance from the contact point CP to the right boundary of the first touch electrode 22a is greater than the resistance from the contact point CP to the left boundary of the second touch electrode 22b.

Therefore, when a common voltage is applied to the first and second touch electrodes 22a and 22b for a display operation, the voltage drop and delay caused by the resistance difference cause the contact between the right edge of the first touch electrode 22a and the second touch electrode 22a. The common voltages at the left boundary of the second touch electrode 22b have different values from each other, and the difference between these common voltages appears as a difference in luminance in a display operation, thereby improving the display quality of the self-capacitance type in-cell type touch display device 10. It is lowered.

The present invention has been proposed to solve these problems, and by making the signal applying path including the touch wiring have different resistances according to the capacitance of the touch electrode, errors in touch operation and display operation are prevented and accuracy and uniformity are improved. It is an object of the present invention to provide a touch display device that is

Another object of the present invention is to provide a touch display device in which a difference in luminance is prevented and display quality is improved by symmetrically arranging contact points with respect to boundaries of touch electrodes.

In order to solve the above problems, the present invention is a touch panel including a plurality of touch electrodes having different areas, applying a touch scan signal to the plurality of touch electrodes and changing the capacitance of the plurality of touch electrodes. A touch driver that analyzes and detects the position of a touch input, and a plurality of signal applying paths each applying the touch scan signal to the plurality of touch electrodes and each having a resistance inversely proportional to the area of the plurality of touch electrodes. A touch display device is provided.

The plurality of touch electrodes may include a first touch electrode having a first area and disposed at a corner portion of the touch panel, and a second touch electrode having a second area larger than the first area and disposed at an edge portion of the touch panel. It may include two touch electrodes and a third touch electrode having a third area larger than the second area and disposed in the central portion of the touch panel.

In addition, the plurality of signal applying paths include a first touch wire connected to the first touch electrode and having a first resistance, and a second touch wire connected to the second touch electrode and having a second resistance smaller than the first resistance. A touch wire and a third touch wire connected to the third touch electrode and having a third resistance smaller than the second resistance may be included.

The first to third touch wires may have the same length, and a second width of the second touch wire may be larger than the first width of the first touch wire and smaller than the third width of the third touch wire. have.

In addition, the first touch wire includes a first number of branch lines, the second touch wire includes a second number of branch lines greater than the first number, and the third touch wire includes a greater number of branch lines than the second number. A third number of branch lines may be included.

The plurality of signal applying paths include a first touch wire connected to the first touch electrode, a first element connected between the first touch wire and the touch driver, and connected to the second touch electrode. A second touch wire, a second element connected between the second touch wire and the touch driver, a third touch wire connected to the third touch electrode, and connected between the third touch wire and the touch driver A third element may be included.

In addition, the first element is a first transistor having a first W/L ratio, the second element is a second transistor having a second W/L ratio greater than the first W/L ratio, and the third element is It may be a third transistor having a third W/L ratio greater than the second W/L ratio.

The first element is a first transistor controlled to have a first turn-on resistance, and the second element is a second transistor controlled to have a second turn-on resistance smaller than the first turn-on resistance. , The third element may be a third transistor controlled to have a third turn-on resistance smaller than the second turn-on resistance.

In addition, the plurality of signal applying paths include a plurality of touch wires connected to the plurality of touch electrodes through a plurality of contact points, respectively, and the plurality of contact points of the plurality of touch electrodes adjacent in the horizontal direction, The plurality of touch electrodes may be arranged symmetrically with respect to the boundary.

According to the present invention, the signal applying path including the touch wiring has different resistances according to the capacitance of the touch electrode, thereby preventing errors in touch operation and display operation and improving accuracy and uniformity.

In addition, the present invention has an effect of improving display quality by preventing a luminance difference by symmetrically arranging the contact point with respect to the boundary of the touch electrode.

1 is a diagram illustrating a conventional in-cell type touch display device;
2 is a diagram illustrating an in-cell type touch display device according to a first embodiment of the present invention;
3 is a diagram illustrating an in-cell type touch display device according to a second embodiment of the present invention;
4 is a diagram illustrating an in-cell type touch display device according to a third embodiment of the present invention;
5 is a diagram illustrating an in-cell type touch display device according to a fourth embodiment of the present invention.
6 is a diagram illustrating an in-cell type touch display device according to a fifth embodiment of the present invention.
7 is a diagram illustrating an in-cell type touch display device according to a sixth embodiment of the present invention;
8 is a diagram illustrating an in-cell type touch display device according to a seventh embodiment of the present invention.

Hereinafter, a touch display device according to the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a diagram illustrating an in-cell type touch display device according to a first embodiment of the present invention, and particularly shows a self-capacitance type in-cell type touch display device.

As shown in FIG. 2 , the self-capacitance type in-cell touch display device 110 according to the first embodiment of the present invention includes a touch panel 120 and a touch driver 130 .

The touch panel 120 includes a plurality of touch electrodes 122 disposed on a substrate and a plurality of touch wires 124 connecting the plurality of touch electrodes 122 and the touch driver 130, respectively. Among the touch electrodes 122 of the touch panel 120, the touch electrode 122 at the center has a cross shape, the touch electrode 122 at the edge of the touch panel 120 has a “T” shape, and the touch panel 120 ) The corner portion of the touch electrode 122 has an “L” shape.

For example, the plurality of touch electrodes 122 include first to third touch electrodes 122a, 122b, and 122c, and the first to third touch electrodes 122a, 122b, and 122c each have an "L" shape. It may have a shape, a “T” shape, or a cross shape.

Also, the plurality of touch wires 124 connected to the plurality of touch electrodes 122 adjacent in the horizontal direction have the same width and length, and as a result, the signal applying path including the plurality of touch wires 124 has the same resistance. have

For example, the plurality of touch wires 124 include first to third touch wires 124a, 124b, and 124c, and the first to third touch wires 124a, 124b, and 124c have the same width and length. and may be connected to the first to third touch electrodes 122a, 122b, and 122c, respectively.

Although not shown, the touch panel 120 may be a display panel including first and second substrates facing each other and spaced apart from each other, and a liquid crystal layer between the first and second substrates, and the plurality of touch electrodes 122 are It may be a common electrode that is separated for each area corresponding to a plurality of pixels of the first or second substrate, respectively. At this time, the touch panel 120 performs a touch operation using a touch scan signal or a display operation using a common voltage. can be performed.

The touch driver 130 applies a touch scan signal to the plurality of touch electrodes 122 of the touch panel 120 and analyzes the change in capacitance of the plurality of touch electrodes 122 according to the applied touch scan signal. The position of the touch input of the touch panel 120 is sensed.

Although not shown, the in-cell type touch display device 110 may further include a display driver for supplying a gate voltage, a data voltage, and a common voltage to the touch panel 120 for a display operation. ) can also be integrated.

In the self-capacitance type in-cell type touch display device 110 according to the first embodiment of the present invention, most of the plurality of touch electrodes 122 are formed in a cross shape, respectively, so that the plurality of touch electrodes 122 Accuracy or touch resolution for the position of a touch input is improved without reducing the area and increasing the number of touch wires 124, or increasing the area of the touch electrodes 122 while maintaining the same touch resolution By reducing the number of wires 124, design freedom can be improved and the load of the touch driver 130 can be reduced, thereby reducing manufacturing cost.

For example, although the two points E and F respectively located on the two adjacent touch electrodes 122 are spaced apart at a relatively close distance, they are detected as different positions by the touch driver 130, so errors in touch operation occur. is prevented, improving touch accuracy and touch resolution.

However, in the self-capacitance type in-cell touch display device 110 according to the first embodiment of the present invention, the plurality of touch electrodes 122 have different areas according to their positions on the touch panel 120, Due to these different areas, the plurality of touch electrodes 122 have different capacitances (C), and luminance uniformity or touch accuracy may be lowered due to the different capacitances.

For example, the “T”-shaped second touch electrode 122b may have an area twice that of the “L”-shaped first touch electrode 122a, and the cross-shaped third touch electrode ( 122c) may have an area four times that of the “L”-shaped first touch electrode 122a.

In this case, since the first to third touch wires 124a, 124b, and 124c have substantially the same width and length, the first to third touch wires 124a, 124b, and 124c have substantially the same resistance (R). ), and as a result, the touch scan signal or common voltage applied to the first to third touch electrodes 122a, 122b, and 122c through the first to third touch wires 124a, 124b, and 124c is a resistor (R) and a different delay or load corresponding to the product RC of the capacitance C.

Therefore, during a display operation of the touch panel 120, different common voltages are applied to the first to third touch electrodes 122a, 122b, and 122c, resulting in luminance non-uniformity and deterioration in display quality, or when the touch panel 120 touches the touch panel 120. During operation, different touch scan voltages are applied to the first to third touch electrodes 122a, 122b, and 122c, and thus touch accuracy may deteriorate.

In order to solve this problem, in another embodiment, the resistance of the signal applying path including the plurality of touch wires 122 may be set differently to compensate for the difference in capacitance, which will be described with reference to the drawings.

FIG. 3 is a diagram showing an in-cell type touch display device according to a second embodiment of the present invention, particularly showing a self-capacitance type in-cell type touch display device, and showing the same parts as the first embodiment. The description is omitted.

As shown in FIG. 3 , the self-capacitance type in-cell touch display device 210 according to the second embodiment of the present invention includes a touch panel 220 and a touch driver 230 .

The touch panel 220 includes a plurality of touch electrodes 222 disposed on a substrate and a plurality of touch wires 224 connecting the plurality of touch electrodes 222 and the touch driver 230, respectively. Among the touch electrodes 222 of the touch panel 220, the touch electrode 222 at the center has a cross shape, and the touch electrode 222 at the edge (side) of the touch panel 220 has a “T” shape, The touch electrodes 222 at the corners of the touch panel 220 have an “L” shape.

For example, the plurality of touch electrodes 222 include first to third touch electrodes 222a, 222b, and 222c, and the first to third touch electrodes 222a, 222b, and 222c each have an “L” shape. It may have a shape, a “T” shape, or a cross shape.

At this time, the “L” shaped first touch electrode 222a has a first area A1, and the “T” shaped second touch electrode 222b has a first area A1 that is approximately twice the first area A1. Since it has 2 areas (A2 = 2A1) and the cross-shaped third touch electrode 222c has a third area (A3 = 4A1) that is about 4 times the first area A1, the first touch electrode 222a The first capacitance C1 of is about 1/4 of the third capacitance C3 of the third touch electrode 222c (C1=C3/4), and the second capacitance of the second touch electrode 222b The capacitance C2 is about 1/2 of the third capacitance C3 of the third touch electrode 222c (C2=C3/2).

Also, the plurality of touch wires 224 connected to the plurality of touch electrodes 222 adjacent in the horizontal direction have the same width and different lengths in inverse proportion to the area of the plurality of touch electrodes 222, and as a result, The signal applying path including the touch wire 224 has different resistances that are inversely proportional to the area of the plurality of touch electrodes 222 .

For example, the plurality of touch wires 224 include first to third touch wires 224a, 224b, and 224c, and the first to third touch wires 224a, 224b, and 224c have the same width, Each has first to third lengths L1, L2, and L3 and may be connected to the first to third touch electrodes 222a, 222b, and 222c.

At this time, the first length L1 of the first touch wire 224a is about 4 times the third length L3 of the third touch wire 224c (L1 = 4L3), and the length of the second touch wire 224b is about 4 times. The second length L2 may be about twice the third length L3 of the third touch wire 224c (L2=2L3), and in this case, the horizontal direction of the first and second touch wires 224a and 224b The length (d) of the component is about 1/8 of the third length (L3) (d = L3/8), and the first and second touch wires 224a and 224b have 16 and 8 horizontal components, respectively. can have

That is, the first resistance R1 of the first touch wire 224a is about 4 times the third resistance R3 of the third touch wire 224c (R1 = 4R3), and The second resistor R2 is about twice the third resistor R3 of the third touch wire 224c (R2 = 2R3).

Therefore, the first resistor R1, which is a delay or load felt by the voltage or signal applied to the first touch electrode 222a through the first signal applying path including the first touch wire 224a, and the first capacitance C1 (R1C1 = (4R3) * (C3/4) = R3C3) and the second touch electrode 222b through the second signal applying path including the second touch wire 224b. The product of the second resistance (R2) and the second capacitance (C2), which is the delay or load felt by the voltage or signal applied to ) (R2C2 = (2R3) * (C3/2) = R3C3) ) is a third resistance (delay or load) felt by the voltage or signal applied to the third touch electrode 222c through the third signal applying path including the third touch wire 224c, respectively. R3) and the third capacitance (C3) is equal to the product (R3C3).

As such, in the self-capacitance type in-cell touch display device 210 according to the second embodiment of the present invention, the signal applying path including the plurality of touch wires 224 is the area of the plurality of touch electrodes 222. By having a resistance inversely proportional to , the common voltage or touch scan signal applied to the plurality of touch electrodes 222 through the signal application path including the plurality of touch wires 224 has resistance (R) and capacitance (C) As a result, the same common voltage is applied to the plurality of touch electrodes 222 during the display operation of the touch panel 220, resulting in uneven luminance. This improves display quality and improves touch accuracy by applying the same touch scan voltage to a plurality of touch electrodes 222 during a touch operation of the touch panel 220 .

In addition, by forming most of the plurality of touch electrodes 222 in a cross shape, respectively, the accuracy of the position of the touch input or the touch without reducing the area of the plurality of touch electrodes 222 and increasing the number of the plurality of touch wires 224 By increasing the resolution or maintaining the same touch resolution, increasing the area of the plurality of touch electrodes 222 and reducing the number of the plurality of touch wires 224, the degree of freedom in design is improved and the load of the touch driver 230 is reduced. This can reduce manufacturing cost.

Meanwhile, in another embodiment, the signal applying path including the touch wire may have different resistances by changing the line width, which will be described with reference to the drawings.

FIG. 4 is a diagram showing an in-cell type touch display device according to a third embodiment of the present invention, particularly showing a self-capacitance type in-cell type touch display device, and showing the same parts as the first embodiment. The description is omitted.

As shown in FIG. 4 , the self-capacitance in-cell type touch display device 310 according to the third embodiment of the present invention includes a touch panel 320 and a touch driver 330 .

The touch panel 320 includes a plurality of touch electrodes 322 disposed on a substrate and a plurality of touch wires 324 connecting the plurality of touch electrodes 322 and the touch driver 330, respectively. Among the touch electrodes 322 of the touch panel 320, the touch electrode 322 at the center has a cross shape, and the touch electrode 322 at the edge of the touch panel 320 has a “T” shape. ) The corner portion of the touch electrode 322 has an “L” shape.

For example, the plurality of touch electrodes 322 include first to third touch electrodes 322a, 322b, and 322c, and the first to third touch electrodes 322a, 322b, and 322c each have an “L” shape. It may have a shape, a “T” shape, or a cross shape.

At this time, the “L” shaped first touch electrode 322a has a first area A1, and the “T” shaped second touch electrode 322b has a first area A1 that is approximately twice the first area A1. Since it has 2 areas (A2 = 2A1) and the cross-shaped third touch electrode 322c has a third area (A3 = 4A1) that is about 4 times the first area A1, the first touch electrode 322a The first capacitance C1 of is about 1/4 of the third capacitance C3 of the third touch electrode 322c (C1=C3/4), and the second capacitance of the second touch electrode 322b The capacitance C2 is about 1/2 of the third capacitance C3 of the third touch electrode 322c (C2 = C3/2).

Also, the plurality of touch wires 324 connected to the plurality of touch electrodes 322 adjacent in the horizontal direction have the same length and different widths in inverse proportion to the area of the plurality of touch electrodes 322, and as a result, The signal applying path including the touch wire 324 has different resistances that are inversely proportional to the area of the plurality of touch electrodes 322 .

For example, the plurality of touch wires 324 include first to third touch wires 324a, 324b, and 324c, and the first to third touch wires 324a, 324b, and 324c have the same length, Each of the first to third widths w1 , w2 , and w3 may be connected to the first to third touch electrodes 322a , 322b , and 322c.

At this time, the first width w1 of the first touch wire 324a is about 1/4 of the third width w3 of the third touch wire 324c (w1 = w3/4), and the second touch wire ( The second width w2 of 324b) may be about 1/2 of the third width w3 of the third touch wire 324c (w2 = w3/2).

That is, the first resistance R1 of the first touch wire 324a is about 4 times the third resistance R3 of the third touch wire 324c (R1 = 4R3), and The second resistor R2 is about twice the third resistor R3 of the third touch wire 324c (R2 = 2R3).

Therefore, the first resistor R1, which is a delay or load felt by the voltage or signal applied to the first touch electrode 322a through the first signal applying path including the first touch wire 324a, and the first capacitance C1 (R1C1 = (4R3) * (C3/4) = R3C3) and the second touch electrode 322b through the second signal applying path including the second touch wire 324b. The product of the second resistance (R2) and the second capacitance (C2), which is the delay or load felt by the voltage or signal applied to ) (R2C2 = (2R3) * (C3/2) = R3C3) ) is a third resistance (delay or load) felt by the voltage or signal applied to the third touch electrode 322c through the third signal applying path including the third touch wire 324c, respectively. R3) and the third capacitance (C3) is equal to the product (R3C3).

As such, in the self-capacitance type in-cell touch display device 310 according to the third embodiment of the present invention, the signal applying path including the plurality of touch wires 324 is the area of the plurality of touch electrodes 322. By having a resistance inversely proportional to , the common voltage or touch scan signal applied to the plurality of touch electrodes 322 through the signal application path including the plurality of touch wires 324 has resistance (R) and capacitance (C) As a result, the same common voltage is applied to the plurality of touch electrodes 322 during the display operation of the touch panel 320, resulting in uneven luminance. This improves display quality and improves touch accuracy by applying the same touch scan voltage to a plurality of touch electrodes 322 during a touch operation of the touch panel 320 .

And, by forming most of the plurality of touch electrodes 322 in a cross shape, respectively, the accuracy of the position of the touch input or the touch without reducing the area of the plurality of touch electrodes 322 and increasing the number of the plurality of touch wires 324. The degree of freedom in design is improved and the load of the touch driver 330 is reduced by increasing the resolution or increasing the area of the plurality of touch electrodes 322 and reducing the number of the plurality of touch wires 324 while maintaining the same touch resolution. This can reduce manufacturing cost.

Meanwhile, in another embodiment, branch lines may be formed so that signal applying paths including touch wires may have different resistances, which will be described with reference to the drawings.

FIG. 5 is a diagram showing an in-cell type touch display device according to a fourth embodiment of the present invention, particularly showing a self-capacitance type in-cell type touch display device, and showing the same parts as the first embodiment. The description is omitted.

As shown in FIG. 5 , the self-capacitance in-cell type touch display device 410 according to the fourth embodiment of the present invention includes a touch panel 420 and a touch driver 430 .

The touch panel 420 includes a plurality of touch electrodes 422 disposed on a substrate and a plurality of touch wires 424 connecting the plurality of touch electrodes 422 and the touch driver 430, respectively. Among the touch electrodes 422 of the touch panel 420, the touch electrode 422 at the center has a cross shape, and the touch electrode 422 at the edge of the touch panel 420 has a “T” shape. ) The corner portion of the touch electrode 422 has an “L” shape.

For example, the plurality of touch electrodes 422 include first to third touch electrodes 422a, 422b, and 422c, and the first to third touch electrodes 422a, 422b, and 422c each have an “L” shape. It may have a shape, a “T” shape, or a cross shape.

At this time, the “L” shaped first touch electrode 422a has a first area A1, and the “T” shaped second touch electrode 422b has a first area A1 that is approximately twice the first area A1. Since it has 2 areas (A2 = 2A1) and the cross-shaped third touch electrode 422c has a third area (A3 = 4A1) that is about 4 times the first area A1, the first touch electrode 422a The first capacitance C1 of is about 1/4 of the third capacitance C3 of the third touch electrode 422c (C1=C3/4), and the second capacitance of the second touch electrode 422b The capacitance C2 is about 1/2 of the third capacitance C3 of the third touch electrode 422c (C2 = C3/2).

In addition, the plurality of touch wires 424 connected to the plurality of touch electrodes 422 adjacent in the horizontal direction have branch lines having the same length and the same width, the number of which is inversely proportional to the area of the plurality of touch electrodes 422. As a result, the signal applying path including the plurality of touch wires 424 has different resistances that are inversely proportional to the area of the plurality of touch electrodes 422 .

For example, the plurality of touch wires 424 include first to third touch wires 424a, 424b, and 424c, and each of the first to third touch wires 424a, 424b, and 424c is one (first) to third touch wires 424a, 424b, and 424c. 1 number), 2 (second number), and 4 (third number) branch lines, and may be connected to the first to third touch electrodes 422a, 422b, and 422c.

That is, the first resistance R1 of the first touch wire 424a is about 4 times the third resistance R3 of the third touch wire 424c (R1 = 4R3), and The second resistor R2 is about twice the third resistor R3 of the third touch wire 424c (R2 = 2R3).

In the fourth embodiment, branch lines are formed at the central portion of the touch panel 420 where a plurality of touch electrodes 422 are disposed, but in other embodiments, branch lines are formed at the edges of the touch panel 420 to touch It may be connected to a plurality of touch electrodes 422 from the side facing the driver 430 .

Therefore, the first resistor R1, which is a delay or load felt by the voltage or signal applied to the first touch electrode 422a through the first signal applying path including the first touch wire 424a, and the first capacitance C1 (R1C1 = (4R3) * (C3/4) = R3C3) and the second touch electrode 422b through the second signal applying path including the second touch wire 424b. The product of the second resistance (R2) and the second capacitance (C2), which is the delay or load felt by the voltage or signal applied to ) (R2C2 = (2R3) * (C3/2) = R3C3) ) is a third resistance (delay or load) felt by the voltage or signal applied to the third touch electrode 422c through the third signal applying path including the third touch wire 424c, respectively. R3) and the third capacitance (C3) is equal to the product (R3C3).

As such, in the self-capacitance type in-cell touch display device 410 according to the fourth embodiment of the present invention, the signal applying path including the plurality of touch wires 424 is the area of the plurality of touch electrodes 422. By having a resistance inversely proportional to , the common voltage or touch scan signal applied to the plurality of touch electrodes 422 through the signal application path including the plurality of touch wires 424 has resistance (R) and capacitance (C) As a result, the same common voltage is applied to the plurality of touch electrodes 422 during the display operation of the touch panel 420, resulting in uneven luminance. This improves display quality and improves touch accuracy by applying the same touch scan voltage to a plurality of touch electrodes 422 during a touch operation of the touch panel 420 .

And, by forming most of the plurality of touch electrodes 422 in a cross shape, respectively, the accuracy of the position of the touch input or the touch without reducing the area of the plurality of touch electrodes 422 and increasing the number of the plurality of touch wires 424. The degree of freedom in design is improved and the load of the touch driver 430 is reduced by increasing the resolution or increasing the area of the plurality of touch electrodes 422 and reducing the number of the plurality of touch wires 424 while maintaining the same touch resolution. This can reduce manufacturing cost.

Meanwhile, in another embodiment, a signal applying path including a touch wire and an element may have different resistances by using an element such as a transistor or a diode, which will be described with reference to the drawings.

FIG. 6 is a diagram showing an in-cell type touch display device according to a fifth embodiment of the present invention, particularly showing a self-capacitance type in-cell type touch display device, and the same parts as the first embodiment. The description is omitted.

As shown in FIG. 6 , the self-capacitance type in-cell touch display device 510 according to the fifth embodiment of the present invention includes a touch panel 520 and a touch driver 530 .

The touch panel 520 includes a plurality of touch electrodes 522 disposed on a substrate and a plurality of touch wires 524 connecting the plurality of touch electrodes 522 and the touch driver 530, respectively. Among the touch electrodes 522 of the touch panel 520, the touch electrodes 522 at the center of the touch panel 520 have a cross shape, and the touch electrodes 522 at the edges of the touch panel 520 have a “T” shape. ) The corner portion of the touch electrode 522 has an “L” shape.

For example, the plurality of touch electrodes 522 include first to third touch electrodes 522a, 522b, and 522c, and the first to third touch electrodes 522a, 522b, and 522c each have an "L" shape. It may have a shape, a “T” shape, or a cross shape.

At this time, the “L” shaped first touch electrode 522a has a first area A1, and the “T” shaped second touch electrode 522b has a first area A1 that is about twice the first area A1. Since it has 2 areas (A2 = 2A1) and the cross-shaped third touch electrode 522c has a third area (A3 = 4A1) that is about 4 times the first area A1, the first touch electrode 522a The first capacitance C1 of is about 1/4 of the third capacitance C3 of the third touch electrode 522c (C1=C3/4), and the second capacitance of the second touch electrode 522b The capacitance C2 is about 1/2 of the third capacitance C3 of the third touch electrode 522c (C2=C3/2).

In addition, the plurality of touch wires 524 connected to the plurality of touch electrodes 522 adjacent in the horizontal direction have the same length and the same width, and the W/L ratio (W) proportional to the area of the plurality of touch electrodes 522 /L ratio), and as a result, the signal applying path including the plurality of transistors and the plurality of touch wires 524 has different resistances that are inversely proportional to the area of the plurality of touch electrodes 522 .

For example, the plurality of touch wires 524 include first to third touch wires 524a, 524b, and 524c and are connected to first to third touch electrodes 522a, 522b, and 522c. First to third transistors T1 , T2 , and T3 may be connected between the third touch wires 524a , 524b , and 524c and the touch driver 530 , respectively.

At this time, the first W/L ratio (W1/L1) of the first transistor T1 is about 1/4 of the third W/L ratio (W3/L3) of the third transistor T3 (W1/L1 = (W3 /L3)/4), the second W/L ratio (W2/L2) of the second transistor T2 may be about 1/2 of the third W/L ratio (W3/L3) of the third transistor T3. (W2/L2=(W3/L3)/2).

Since the W/L ratio in the transistor is inversely proportional to the turn-on resistance, the first touch wire 524a and the first resistor R1 of the first transistor T1 are connected to the third touch wire 524c and It is about 4 times the third resistance R3 of the third transistor T3 (R1 = 4R3), and the second resistance R2 of the second touch wire 524b and the second transistor T2 is the third touch wire (524c) and the third resistance (R3) of the third transistor (T3) is about twice (R2 = 2R3).

Here, it is assumed that the resistance of the first to third touch wires 524a, 524b, and 524c is negligibly smaller than the turn-on resistance of the first to third transistors T1, T2, and T3. In this case, the resistance of the first to third touch wires 524a, 524b, and 524c and the first to third transistors T1 and T2 are adjusted by adjusting the W/L ratio of the first to third transistors T1, T2, and T3. , T3) The sum of each turn-on resistance may satisfy the above relationship.

Therefore, the delay or load felt by the voltage or signal applied to the first touch electrode 522a through the first signal application path including the first transistor T1 and the first touch wire 524a Including the product of the first resistance (R1) and the first capacitance (C1) (R1C1=(4R3)*(C3/4)=R3C3), the second transistor T2, and the second touch wire 524b. The product of the second resistance R2, which is the delay or load felt by the voltage or signal applied to the second touch electrode 522b through the second signal application path, and the second capacitance C2 ( R2C2 = (2R3) * (C3/2) = R3C3) is applied to the third touch electrode 522c through the third signal applying path including the third transistor T3 and the third touch wire 524c, respectively. It is equal to the product (R3C3) of the third resistance (R3) and the third capacitance (C3), which is the delay or load felt by the applied voltage or signal.

In the fifth embodiment, transistors having different W/L ratios are connected to a plurality of touch wires 524 as an example, but in another embodiment, the plurality of touch wires 524 have different numbers of transistors having the same W/L ratio. , or diodes of different sizes or numbers may be connected instead of transistors.

In this way, in the self-capacitance type in-cell touch display device 510 according to the fifth embodiment of the present invention, the plurality of transistors T connected to the plurality of touch wires 524 are the plurality of touch electrodes 522 Is a signal including a plurality of transistors T and a plurality of touch wires 524 by having a W/L ratio proportional to the area of ) (ie, resistance inversely proportional to the area of the plurality of touch electrodes 522) The common voltage or touch scan signal applied to the plurality of touch electrodes 522 through the path feels the same delay or load corresponding to the product RC of the resistance R and the capacitance C. As a result, during the display operation of the touch panel 520, the same common voltage is applied to the plurality of touch electrodes 522 to prevent luminance non-uniformity, thereby improving display quality, and during the touch operation of the touch panel 520, a plurality of touches The same touch scan voltage is applied to the electrode 522 to improve touch accuracy.

In addition, by forming most of the plurality of touch electrodes 522 in a cross shape, respectively, the accuracy of the position of the touch input or the touch without reducing the area of the plurality of touch electrodes 522 and increasing the number of the plurality of touch wires 524 By improving the resolution or maintaining the same touch resolution, increasing the area of the plurality of touch electrodes 522 and reducing the number of the plurality of touch wires 524, the degree of freedom in design is improved and the load of the touch driver 530 is reduced. This can reduce manufacturing cost.

Meanwhile, in another embodiment, a signal applying path including a touch wire and an element may have different resistances by using an element such as a transistor, which will be described with reference to the drawings.

FIG. 7 is a diagram showing an in-cell type touch display device according to a sixth embodiment of the present invention, particularly showing a self-capacitance type in-cell type touch display device, and showing the same parts as the first embodiment. The description is omitted.

As shown in FIG. 7 , the in-cell type touch display device 610 of the self-capacitance method according to the sixth embodiment of the present invention includes a touch panel 620 and a touch driver 630 .

The touch panel 620 includes a plurality of touch electrodes 622 disposed on a substrate and a plurality of touch wires 624 connecting the plurality of touch electrodes 622 and the touch driver 630, respectively. Among the touch electrodes 622 of the touch panel 620, the touch electrodes 622 at the center of the touch panel 620 have a cross shape, and the touch electrodes 622 at the edges of the touch panel 620 have a “T” shape. ) The corner portion of the touch electrode 622 has an “L” shape.

For example, the plurality of touch electrodes 622 include first to third touch electrodes 622a, 622b, and 622c, and the first to third touch electrodes 622a, 622b, and 622c each have an “L” shape. It may have a shape, a “T” shape, or a cross shape.

At this time, the “L” shaped first touch electrode 622a has a first area A1, and the “T” shaped second touch electrode 622b has a first area A1 that is approximately twice the first area A1. Since it has 2 areas (A2 = 2A1) and the cross-shaped third touch electrode 622c has a third area (A3 = 4A1) that is about 4 times the first area A1, the first touch electrode 622a The first capacitance C1 of is about 1/4 of the third capacitance C3 of the third touch electrode 622c (C1=C3/4), and the second capacitance of the second touch electrode 622b The capacitance C2 is about 1/2 of the third capacitance C3 of the third touch electrode 622c (C2=C3/2).

Also, the plurality of touch wires 624 connected to the plurality of touch electrodes 622 adjacent in the horizontal direction have the same length and the same width, and each have a turn-on resistance that is inversely proportional to the area of the plurality of touch electrodes 622. As a result, the signal applying path including the plurality of transistors and the plurality of touch wires 624 has different resistances that are inversely proportional to the area of the plurality of touch electrodes 622 .

For example, the plurality of touch wires 624 include first to third touch wires 624a, 624b, and 624c and are connected to the first to third touch electrodes 622a, 622b, and 622c. First to third transistors T1 , T2 , and T3 may be connected between the third touch wires 624a , 624b , and 624c and the touch driver 630 , respectively.

At this time, the first to third voltages V1, V2, and V3 are applied to the gates of the first to third transistors T1, T2, and T3, respectively, to the channels of the first to third transistors T1, T2, and T3. are controlled to have first to third turn-on resistances, the first turn-on resistance is about 4 times the third turn-on resistance, and the second turn-on resistance is about 3 times the third turn-on resistance. controlled to double.

Accordingly, the first resistance R1 of the first touch wire 624a and the first transistor T1 is about 4 times the third resistance R3 of the third touch wire 624c and the third transistor T3. (R1 = 4R3), the second resistor R2 of the second touch wire 624b and the second transistor T2 is the third resistor R3 of the third touch wire 624c and the third transistor T3 is about twice that of (R2=2R3).

Here, it is assumed that the resistance of the first to third touch wires 624a, 624b, and 624c is negligibly smaller than the turn-on resistance of the first to third transistors T1, T2, and T3. In this case, the first to third voltages (V1, V2, V3) applied to the first to third transistors (T1, T2, T3) are adjusted to control the first to third touch wires (624a, 624b, 624c) respectively. The above relationship may be satisfied by the sum of the resistance and the turn-on resistance of each of the first to third transistors T1, T2, and T3.

Therefore, the delay or load felt by the voltage or signal applied to the first touch electrode 622a through the first signal application path including the first transistor T1 and the first touch wire 624a Including the product of the first resistance (R1) and the first capacitance (C1) (R1C1=(4R3)*(C3/4)=R3C3), the second transistor T2, and the second touch wire 624b. The product of the second resistance R2, which is the delay or load felt by the voltage or signal applied to the second touch electrode 622b through the second signal applying path, and the second capacitance C2 ( R2C2 = (2R3) * (C3/2) = R3C3) is applied to the third touch electrode 622c through the third signal applying path including the third transistor T3 and the third touch wire 624c, respectively. It is equal to the product (R3C3) of the third resistance (R3) and the third capacitance (C3), which is the delay or load felt by the applied voltage or signal.

In this way, in the self-capacitance type in-cell touch display device 610 according to the sixth embodiment of the present invention, the plurality of transistors T connected to the plurality of touch wires 624 are the plurality of touch electrodes 622 ) is controlled to have turn-on resistance that is inversely proportional to the area of ), so that a common voltage applied to the plurality of touch electrodes 622 through a signal applying path including a plurality of transistors T and a plurality of touch wires 624 or The touch scan signal feels the same delay or load corresponding to the product (RC) of the resistance (R) and the capacitance (C), and as a result, during the display operation of the touch panel 620, a number of touches The same common voltage is applied to the electrodes 622 to prevent luminance non-uniformity, thereby improving display quality, and when the touch panel 620 is touched, the same touch scan voltage is applied to a plurality of touch electrodes 622 to improve touch accuracy. do.

In addition, by forming most of the plurality of touch electrodes 622 in a cross shape, respectively, the accuracy of the position of the touch input or the touch without reducing the area of the plurality of touch electrodes 622 and increasing the number of the plurality of touch wires 624 By improving the resolution or maintaining the same touch resolution, increasing the area of the plurality of touch electrodes 622 and reducing the number of the plurality of touch wires 624, the degree of freedom in design is improved and the load of the touch driver 630 is reduced. This can reduce manufacturing cost.

Meanwhile, in another embodiment, the luminance non-uniformity may be improved by symmetrically arranging the contact point between the touch electrode and the touch wire with respect to the boundary of the touch electrode, which will be described with reference to the drawings.

FIG. 8 is a view showing an in-cell type touch display device according to a seventh embodiment of the present invention, and particularly shows a self-capacitance type in-cell type touch display device.

As shown in FIG. 8 , the in-cell type touch display device 710 according to the seventh embodiment of the present invention includes a touch panel 720 and a touch driver 730 .

The touch panel 720 includes a plurality of touch electrodes 722 disposed on a substrate and a plurality of touch wires 724 connecting the plurality of touch electrodes 722 and the touch driver 730, respectively. Each of the touch electrodes 722 has a rectangular shape.

Also, the plurality of touch wires 724 connected to the plurality of touch electrodes 722 adjacent in the horizontal direction have the same length and the same width.

The touch driver 730 applies a touch scan signal to the plurality of touch electrodes 722 of the touch panel 720 and analyzes the change in capacitance of the plurality of touch electrodes 722 according to the applied touch scan signal. The position of the touch input of the touch panel 720 is sensed.

Here, the plurality of touch electrodes 722 are connected to the plurality of touch wires 724 through contact points CP, respectively, and the contact points CP are symmetrical with respect to the boundary between adjacent touch electrodes 722 in the horizontal direction. placed hostilely.

Specifically, in one vertical row of the plurality of touch electrodes 722, the leftmost touch wire 724 is connected to the uppermost touch electrode 722 and the rightmost touch wire 724 is connected to the lowermost touch electrode. 722, and between them, from left to right, the touch wires 724 are connected to the lower touch electrodes 722, and in the horizontally adjacent vertical column, the leftmost touch wire 724 is the lowermost touch wire 724. electrode 722, the rightmost touch wire 724 is connected to the uppermost touch electrode 722, and between them, from left to right, the touch wire 724 can be connected to the upper touch electrode 722. have.

For example, since the first and second touch electrodes 722a and 722b are connected to the first and second touch wires 724a and 724b through left and right contact points CP, respectively, the first touch electrode ( The point G of the right boundary of 722a) and the point H of the left boundary of the second touch electrode 722b are located at a relatively far distance from the contact point CP, and as a result, they are separated from the contact point CP. The resistance up to the right boundary of the first touch electrode 722a and the resistance from the contact point CP to the left boundary of the second touch electrode 722b are substantially the same.

In addition, since the third and fourth touch electrodes 722c and 722d are connected to the third and fourth touch wires 724c and 724d through the right and left contact points CP, respectively, the third touch electrode 722c The point (I) of the right boundary of the fourth touch electrode 722d and the point (J) of the left boundary of the fourth touch electrode 722d are each located at a relatively close distance from the contact point CP, and as a result, the third point from the contact point CP. The resistance up to the right boundary of the touch electrode 722c and the resistance from the contact point CP to the left boundary of the fourth touch electrode 722d are substantially the same.

Therefore, when a common voltage is applied to the first and second touch electrodes 722a and 722b and the third and fourth touch electrodes 722c and 722d for a display operation, a voltage drop and delay due to a resistance difference As a result, the common voltage of the right boundary of the first touch electrode 722a and the left boundary of the second touch electrode 722b becomes the same value, and the right boundary of the third touch electrode 722c and the common voltage of the fourth touch electrode 722d ) becomes the same value as each other, and as a result, luminance non-uniformity is prevented in a display operation, and the display quality of the self-capacitance type in-cell type touch display device 710 is improved.

In the seventh embodiment, the square-shaped touch electrode 722 was taken as an example, but in other embodiments, “L”-shaped, “T”-shaped, and cross-shaped touch electrodes are also disposed symmetrically with respect to the touch electrode boundary. Contact points can be applied.

In the above embodiment, an in-cell type touch display device has been taken as an example, but in other embodiments, a signal applying path having resistance inversely proportional to the area of the touch electrode is applied to a touch panel formed separately from the display panel, or a path formed separately from the display panel A symmetrical arrangement of contact points may be applied to the touch panel.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art will variously modify and change the present invention within the scope not departing from the technical spirit and scope of the present invention described in the claims below. You will understand that it can be done.

210: touch display device 220: touch panel
222: touch electrode 224: touch wiring
230: touch driving unit

Claims (12)

a touch panel including a plurality of touch electrodes having different areas;
a touch driver for detecting a position of a touch input by applying a touch scan signal to the plurality of touch electrodes and analyzing a change in capacitance of the plurality of touch electrodes;
A plurality of signal applying paths each of which applies the touch scan signal to the plurality of touch electrodes and each has a resistance inversely proportional to the area of the plurality of touch electrodes.
including,
The plurality of touch electrodes,
a first touch electrode having a first area and a first capacitance and disposed at a corner portion of the touch panel;
a second touch electrode having a second area larger than the first area and a second capacitance larger than the first capacitance and disposed on an edge portion of the touch panel;
A third touch electrode having a third area larger than the second area and a third capacitance larger than the second capacitance and disposed in the central portion of the touch panel
including,
The plurality of signal applying paths,
a first touch wire connected to the first touch electrode and having a first resistance;
a second touch wire connected to the second touch electrode and having a second resistance smaller than the first resistance;
A third touch wire connected to the third touch electrode and having a third resistance smaller than the second resistance
including,
The touch display device of claim 1 , wherein a product of the first resistance and the first capacitance, a product of the second resistance and the second capacitance, and a product of the third resistance and the third capacitance are equal to each other.
delete delete According to claim 1,
The first to third touch wires have the same width,
A second length of the second touch wire is smaller than the first length of the first touch wire and larger than a third length of the third touch wire.
According to claim 1,
The first to third touch wires have the same length,
A second width of the second touch wire is larger than the first width of the first touch wire and smaller than a third width of the third touch wire.
According to claim 1,
The first touch wiring includes a first number of branch lines,
The second touch wiring includes a second number of branch lines greater than the first number,
The third touch wire includes a third number of branch lines greater than the second number.
a touch panel including a plurality of touch electrodes having different areas;
a touch driver for detecting a position of a touch input by applying a touch scan signal to the plurality of touch electrodes and analyzing a change in capacitance of the plurality of touch electrodes;
A plurality of signal applying paths each of which applies the touch scan signal to the plurality of touch electrodes and each has a resistance inversely proportional to the area of the plurality of touch electrodes.
including,
The plurality of touch electrodes,
a first touch electrode having a first area and a first capacitance and disposed at a corner portion of the touch panel;
a second touch electrode having a second area larger than the first area and a second capacitance larger than the first capacitance and disposed on an edge portion of the touch panel;
A third touch electrode having a third area larger than the second area and a third capacitance larger than the second capacitance and disposed in the central portion of the touch panel
including,
The plurality of signal applying paths,
a first touch wire connected to the first touch electrode, and a first element having a first turn-on resistance and connected between the first touch wire and the touch driver;
a second touch wire connected to the second touch electrode, a second element having a second turn-on resistance smaller than the first turn-on resistance, and connected between the second touch wire and the touch driver;
A third element having a third touch wire connected to the third touch electrode, a third turn-on resistance smaller than the second turn-on resistance, and connected between the third touch wire and the touch driver
including,
The product of the first turn-on resistance and the first capacitance, the product of the second turn-on resistance and the second capacitance, and the product of the third turn-on resistance and the third capacitance are each other Same touch display.
According to claim 7,
The first element is a first transistor having a first W/L ratio,
The second element is a second transistor having a second W/L ratio greater than the first W/L ratio,
The third element is a third transistor having a third W/L ratio greater than the second W/L ratio.
According to claim 7,
The first element is a first transistor whose gate voltage is controlled to have the first turn-on resistance;
The second element is a second transistor whose gate voltage is controlled to have the second turn-on resistance;
The third element is a third transistor whose gate voltage is controlled to have the third turn-on resistance.
a touch panel including a plurality of touch electrodes having different areas;
a touch driver for detecting a position of a touch input by applying a touch scan signal to the plurality of touch electrodes and analyzing a change in capacitance of the plurality of touch electrodes;
A plurality of signal applying paths each of which applies the touch scan signal to the plurality of touch electrodes and each has a resistance inversely proportional to the area of the plurality of touch electrodes.
including,
The plurality of signal applying paths include a plurality of touch wires connected to the plurality of touch electrodes through a plurality of contact points, respectively;
The plurality of touch electrodes include first to third touch electrodes sequentially disposed adjacent to each other in a horizontal direction,
The plurality of touch wires include first to third touch wires respectively connected to the first to third touch electrodes through first to third contact points;
The first and second contact points of the first and second touch electrodes are symmetrically disposed with respect to a boundary between the first and second touch electrodes;
The second and third contact points of the second and third touch electrodes are disposed symmetrically with respect to a boundary between the second and third touch electrodes.
According to claim 1,
The first touch electrode has an “L” shape, the second touch electrode has a “T” shape, and the third touch electrode has a cross shape.
According to claim 10,
The resistance from the first contact point to the right boundary of the first touch electrode and the resistance from the second contact point to the left boundary of the second touch electrode are equal to each other,
A resistance from the second contact point to the right boundary of the second touch electrode and a resistance from the third contact point to the left boundary of the third touch electrode are equal to each other.

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