KR20150128187A - Touch window - Google Patents

Abstract

According to one embodiment of the present invention, a touch window includes: a substrate which includes an effective region including multiple unit cells; and a sensing line which is disposed on top of the effective region of the substrate, and does sensing in a time domain measurement method. When the sensing line selects two random points, an impedance difference between the two points is 40% or less of impedance at one point, and the length of the sensing line between the two points is 1 m.

Description

Touch window {TOUCH WINDOW}

An embodiment relates to a touch window.

2. Description of the Related Art In recent years, a touch panel has been applied to an image displayed on a display device in various electronic products by a method of touching an input device such as a finger or a stylus.

The touch panel is typically divided into a resistive touch panel and a capacitive touch panel. The resistance film type touch panel senses that the resistance changes according to the connection between the electrodes when the pressure is applied to the input device, and the position is detected. A capacitance type touch panel senses a change in electrostatic capacitance between electrodes when a finger touches them, thereby detecting the position. Considering the convenience of the manufacturing method and the sensing power, recently, in a small model, the electrostatic capacity method has attracted attention.

Such a touch panel generally requires a plurality of electrodes, and electrodes are usually disposed on different layers. That is, the manufacturing process of the touch panel is complicated, the manufacturing cost is increased, and the thickness of the touch panel is thickened.

Therefore, in recent years, a position detection method for more precise and simple position recognition has been required in addition to such a method.

The embodiment attempts to provide a touch window with improved reliability.

A touch window according to an embodiment includes a substrate including a valid region including a plurality of unit cells; And a sensing line disposed on an effective area of the substrate and sensing the sensing area by a time domain measurement method. When the sensing line selects any two points, 40% of the impedance of the point, and the length of the sensing line between any two points is 1m.

The touch window according to the embodiment can detect the touch position on the sensing line through the TDR method. The sensing line includes one end, which is a starting point connected to the pulse generator, and the other end, which is a final point. At this time, the difference of the impedance per unit length of the sensing line is 40% or less.

Conventionally, the impedance of the sensing line is sharply decreased as the impedance of the sensing line progresses from one end to the other due to a difference in length of a pattern extending in different directions with respect to a node point of the sensing line. As a result, there is a problem in recognizing the reflection pulse, and since the reference point is not clear due to the large noise of the impedance, it is difficult to measure the position.

The touch window according to the embodiment includes a plurality of unit cells including a unit pattern, and the plurality of unit cells extend at least in two different directions. That is, while the unit patterns are repeatedly arranged in at least two different directions, the length difference of the patterns extending in different directions with respect to the node point can be reduced. This reduces the impedance difference between one end of the sensing line and the other end, reduces the impedance noise of the sensing line, and improves the recognition of the touch sensitivity at the end of the sensing line.

Also, this TDR method can reduce the diameter of the touch tip. For example, the diameter of the tip of the tip can be reduced to 0.5 to 0.8 as compared with the conventional capacitance method. Therefore, the touch window according to the embodiment is capable of delicate touch recognition. In addition, the touch sensing speed can be improved as compared with the conventional capacitance type. That is, the touch sensing speed can be increased to several microseconds (microseconds).

1 is a plan view of a touch window according to the first embodiment.
2 and 3 are diagrams for explaining the sensing method of the sensing line.
FIG. 4 is a view showing an effective area and a unit cell of the touch window according to the first embodiment.
5 is a view showing an effective area and a unit cell of the touch window according to the second embodiment.
6 is a view showing an effective area and a unit cell of the touch window according to the third embodiment.
FIG. 7 is a diagram showing an effective area and a unit cell of a touch window according to the fourth embodiment.
FIG. 8 is a view showing an effective area and a unit cell of the touch window according to the fifth embodiment.
9 is a view showing an effective area and a unit cell of a touch window according to the sixth embodiment.

In the description of the embodiments, it is to be understood that each layer (film), area, pattern or structure may be referred to as being "on" or "under / under" Quot; includes all that is formed directly or through another layer. The criteria for top / bottom or bottom / bottom of each layer are described with reference to the drawings.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a plan view of a touch window according to the first embodiment. FIGS. 2 and 3 are diagrams for explaining the sensing method of the sensing line, and FIG. 4 is a view showing the effective area and the unit cell of the touch window according to the first embodiment.

Referring to FIG. 1, a touch window according to an embodiment includes a substrate 10. The substrate 10 includes a valid area AA in which a user's touch command input is possible. A sensing line 100 is formed on the effective area AA. One sensing line 100 may be formed in one effective area AA. Although only one effective area AA and one sensing line 100 are shown in the drawing, the substrate 10 includes a plurality of effective areas AA and includes a plurality of sensing lines 100 .

Although the boundary of the effective area AA and the edge of the substrate 10 are shown on the drawing, the boundary between the edge of the substrate 10 and the effective area AA may be the same. That is, if necessary, the entire surface of the substrate 10 may be the effective area AA.

The substrate 10 may comprise glass or plastic. In one example, the substrate 10 may include tempered glass, semi-tempered glass, soda lime glass, or reinforced plastic.

In addition, the substrate 10 may include an optically isotropic film. For example, the substrate 100 may include COC, COP, polycarbonate (PC), light polymethylmethacrylate (PMMA), and the like. The optically isotropic film can improve the moire phenomenon, blackout phenomenon (a phenomenon in which a screen appears black at a specific angle), and rainbow phenomenon (iridescent spot) due to the same or similar refractive index in any direction. Therefore, the visibility can be improved.

However, the embodiment is not limited thereto, and the substrate 10 may include various materials capable of supporting the sensing line 100 formed thereon.

The sensing line 100 may include a transparent conductive material to allow electricity to flow without disturbing the transmission of light. For this purpose, the sensing line 100 may include at least one of indium tin oxide, indium zinc oxide, copper oxide, tin oxide, zinc oxide, titanium oxide, titanium oxide, and the like. The sensing line 100 may include a nanowire, a photosensitive nanowire film, carbon nanotube (CNT), graphene, or various metals. In particular, the sensing line 100 may include Cu, Au, Ag, Al, Ti, Ni, or an alloy thereof. In addition, the sensing line 100 may include a conductive polymer.

In addition, the sensing line 100 may include a conductive pattern. For example, the conductive pattern may be arranged in a mesh shape. The mesh shape may be randomly formed to prevent moire phenomenon. Moire phenomenon is a pattern caused by superimposing periodic stripes. It is a phenomenon in which neighboring stripes are overlapped and the thickness of the stripes becomes thicker than other stripes. Therefore, in order to prevent such a moire phenomenon, the conductive pattern shape may be variously arranged.

Specifically, the conductive pattern may include an opening portion and a front portion. At this time, the line width of the conductive pattern line portion may be 0.1 μm to 10 μm. Conductive pattern line portions having a line width of 0.1 mu m or less may not be possible in the manufacturing process. When the line width is 10 μm or less, the pattern of the sensing line 100 can be made invisible. Preferably, the line width of the conductive pattern line portion may be 1 탆 to 7 탆. More preferably, the line width of the conductive pattern line portion may be 2 [mu] m to 5 [mu] m.

In addition, the opening portion of the conductive pattern may be arranged in various shapes such as a rectangular shape, a diamond shape, a pentagon, a hexagonal polygonal shape, or a circular shape. That is, the conductive pattern may have a regular shape.

However, the embodiment is not limited thereto, and the conductive pattern may have an irregular shape. That is, the conductive pattern openings may be variously provided in one conductive pattern.

When the sensing line 100 has a mesh shape, the sensing line 100 can be made invisible even if the sensing line 100 is formed of a metal material. In addition, even if the sensing line 100 is applied to a touch window of a large size, the resistance of the touch window can be lowered. Further, when the touch window is bent, it can be bent without causing any physical damage to the sensing line 100. Therefore, the bending characteristic and the reliability of the touch window can be improved.

Referring to FIGS. 2 and 3, the sensing line 100 is sensed by a time domain reflection (TDR) measurement method and can recognize a touch position. That is, the sensing line 100 senses by the time domain measurement method. In the time domain measurement method, a pulse is applied to one end 100a of the sensing line 100, the pulse progresses to the other end 100b of the sensing line 100, And is output from the one end 100a of the sensing line 100. FIG.

Specifically, a pulse is applied to one end 100a of the sensing line 100. [ The pulse A travels along the pattern of the sensing line 100 and a part of the signal B is transmitted at a point (touch point T) where the impedance is larger than the impedance of the applied pulse A , And some signals (C) are reflected and returned. The magnitude of the impedance can be compared with its absolute value.

At this time, the TDR measurement method is a method of detecting the touch position by analyzing the reflected pulse. For example, the touch position can be detected by measuring the time taken for the reflected pulse to arrive. That is, the touch location can be recognized based on the transmission line theory.

In detail, an energy pulse is transmitted to an electrically conductive path (e.g., a sensing line) having a constant impedance. At this time, the sensing line has a characteristic impedance, and when the sensing line is terminated with its characteristic impedance, the reflection pulse is not transmitted. That is, when the sensing line is terminated, there will be no reflected pulse returning to the starting point of the sensing line where the pulse was generated.

On the other hand, if the electrically conductive path is unterminated, or if there is a change in impedance along the electrically conductive path, some or all of the pulse is reflected to the starting point at which the pulse occurred. That is, when the sensing line is non-terminated, there will be a positive reflection pulse returning to the starting point of the sensing line where the transmitted pulse occurred.

Also, if there is an impedance difference anywhere along the sensing line, a reflected pulse will be generated and detected. For example, an increase in capacitance along a sensing line (e.g., a finger touch) may cause the negative reflection pulse to return to the starting point of the sensing line. The time taken for the reflection pulse to reach the starting point is used to determine the distance to the point where the impedance difference occurs.

Accordingly, at the point T where the input device is touched, an impedance larger than the impedance of the pulse passing through the sensing line 100 when non-touching is formed. Accordingly, when the pulse reflected from the touch point is converted into a digital signal and analyzed, data corresponding to a value lower or higher than a threshold value in the time domain can be extracted. Then, x, y (2D) coordinates which are touch coordinates can be recognized based on the address corresponding to the data of the extracted reflected pulse.

The sensing line 100 includes a first end 100a to which a pulse is generated and a second end 100b to which the pulse is transmitted and terminated along the sensing line 100. [ One end (100a) of the sensing line (100) may be connected to the circuit unit (50).

The circuit unit 50 drives and senses the sensing line 100. For example, the circuit unit 50 may include a pulse generator and a TDR measurement unit.

The pulse generator applies a pulse to the sensing line (100). The TDR measuring unit may convert reflected pulse data of an analog type into digital data, extract reflected pulse data corresponding to a value lower or higher than a threshold range in the digitally converted data, .

This TDR measurement method can recognize the touch gesture as well as the touch position recognition. That is, the touch gesture such as the drawing can be recognized. In addition, it is possible to recognize a repetitive touch operation. Therefore, a differentiated user interface can be provided and the user experience can be expanded.

This TDR measurement method can reduce the diameter of the touch tip. For example, the diameter of the touch tip can be reduced to 0.5 to 0.8 as compared with the conventional capacitance method. Therefore, delicate touch recognition is possible. In addition, the touch sensing speed can be improved as compared with the conventional capacitance type. That is, the touch sensing speed can be increased to several microseconds (microseconds).

On the other hand, signal loss may occur due to the electrical characteristics of the sensing line 100. For example, the impedance of the sensing line 100 decreases sharply as it moves from one end 100a to the other end 100b due to the length difference of sensing lines extending in different directions with respect to the node point, It is impossible to extract the data of the touch.

In detail, one effective region where one sensing line is formed is divided into a plurality of unit cells, and the plurality of unit cells are repeatedly disposed adjacent to each other only in one direction. At this time, a sensing line has been studied in which one unit cell includes a U-shaped unit pattern and a plurality of U-shaped unit patterns are repeated in one direction. That is, a plurality of U-shaped unit patterns are formed so as to fill the entire effective area while being repeatedly arranged in one direction. Accordingly, the length of the pattern extending in the first direction and the length of the pattern extending in the second direction among the U-shaped unit patterns are largely formed.

Due to the difference in length of such a pattern, there is a problem in that the impedance value of the sensing line sharply decreases as the time elapses or as it progresses from one end of the sensing line to the other end. As a result, it is difficult to grasp the position by the impedance of the reflection pulse from one end of the sensing line to the other end, and the touch is not recognized in the sensing line adjacent to the other end.

The sensing line 100 according to the present invention can fill the entire surface of the effective area AA by causing the unit patterns to be repeatedly arranged in at least two different directions. Accordingly, it is possible to minimize a difference in the length of the pattern extending in the first direction and the length of the pattern extending in the second direction in the unit pattern, thereby preventing a sharp decrease in the impedance, reducing the noise of the impedance, have.

Referring to FIG. 4, the effective area AA is divided into a plurality of unit cells (UC). The plurality of unit cells UC may include the same pattern (hereinafter, unit pattern). The unit cell UC may be formed in a circular or polygonal shape, and may be formed in a rectangular shape. At this time, the plurality of unit cells UC are repeatedly arranged in at least two different directions.

For example, when the unit cell UC is a quadrangle, the unit cell UC is formed so as to be in contact with the other unit cell UC in the first direction, In a second direction. The first direction and the second direction may be perpendicular to each other.

A sensing line 100 is disposed on the effective area AA of the substrate 10. The sensing line 100 may be disposed on the entire surface of the effective area AA. The sensing line 100 includes a first sensing pattern 101 and a second sensing pattern 102. The first sensing pattern 101 is a unit pattern formed in one unit cell UC and the second sensing pattern 102 is a unit pattern formed in one unit cell UC and a unit pattern formed in another unit cell UC. It is a connection pattern connecting with the formed unit pattern.

In detail, in a plurality of unit cells UC arranged in the effective area AA, one unit pattern is formed in one unit cell UC. The first sensing pattern 101 is a unit pattern formed in the unit cell UC.

The second sensing pattern 102 is a pattern connecting the first sensing pattern 101 formed in one unit cell UC and the first sensing pattern 101 formed in another unit cell UC . At this time, the first sensing pattern 101 and the second sensing pattern 102 may be integrally formed.

The first sensing pattern 101 may include a plurality of node points. The first pattern 101 may include two node points. The first sensing pattern 101 includes patterns extending in different directions with respect to the node point. For example, the first sensing pattern 101 may include a u-shaped pattern, and may include a pattern extending in a first direction and a pattern extending in a second direction with respect to one node point .

At this time, the ratio of the length of the pattern extending in the first direction and the length of the pattern extending in the second direction with respect to one node point may be 1: 5 to 5: 1. Preferably, the ratio of the length of the pattern extending in the first direction to the length of the pattern extending in the second direction with respect to one node point may be 1: 2 to 2: 1. More preferably, the length of the pattern extending in the first direction with respect to one node point and the length of the pattern extending in the second direction may be substantially the same.

Conventionally, a plurality of unit cells including a U-shaped unit pattern are repeatedly disposed in only one direction. At this time, when the entire area of the effective area is filled, the length of the pattern extending in the first direction and the length of the pattern extending in the second direction among the U-shaped unit patterns are largely formed. As a result, there is a problem that the difference in impedance per 1 m of the unit length of the conventional sensing line is 50% or more. That is, when the pulse advances to the other end, the impedance of the sensing line sharply decreases, and the impedance of the reflected pulse is insufficient, so that the touch is not recognized. In other words, conventionally, it is difficult to form a sensing line of 2 m or more with a difference of impedance of 50% or more per 1 m, and a touch is not recognized at a point 2 m or more from one end of the sensing line.

The sensing line 100 according to the present invention has a structure in which the length of the pattern extending in the first direction within the unit pattern and the length of the pattern extending in the second direction are reduced, The impedance difference between the first terminal 100a and the second terminal 100b can be reduced.

More specifically, when two arbitrary points of the sensing line 100 are selected, the impedance of the point adjacent to the other end 100b of the sensing line 100 may be formed to be smaller than the impedance of the point adjacent to the one end 100a . At this time, the difference between the impedances of the two points may be less than 40% of the impedance of one point. For example, the difference between the impedances of the two points may be less than 40% of the impedance of the point adjacent to the one end 100a. In addition, the impedance of the point adjacent to the other end 100b of the sensing line 100 may be formed to be 60% or more of the impedance of the point adjacent to the end 100a. At this time, the distance of the sensing line 100 between any two points may be 1 m.

That is, the difference in impedance per unit length of the sensing line 100 may be 40% or less. The unit length may be 1m. Accordingly, touch recognition can be performed at a position 2 m or more from one end of the sensing line 100, and the sensing line 100 according to the present invention can be applied to a touch window having a larger area than the conventional one.

For example, when the impedance of one end of a conventional sensing line having a line width of 70 m and a length of 1 m is 200?, The impedance at the other end may be 100? Or less. Under the same line width, length and line resistance conditions, the sensing line according to the present invention may have an impedance of 200 Ω at one end and an impedance of 120 Ω or more at the other end.

At this time, a sensing line of 2 m or more may be required to form a 2-inch touch window. Conventionally, it is difficult to form a sensing line of 2 m or more. However, the sensing line 100 according to the present invention can form a sensing line of 2 m or more, and can be applied to a touch window of 2 inches or more.

Preferably, the difference in impedance per unit length of the sensing line 100 may be less than or equal to 20%. More preferably, the difference in impedance per unit length of the sensing line 100 may be less than or equal to 10%. The smaller the difference in impedance per unit length, the more applicable to large touch windows. The difference in impedance per unit length can be controlled by adjusting the difference between the length of the pattern extending in the first direction and the length of the pattern extending in the second direction within the unit pattern of the sensing line 100. For example, For example, when the impedance of one end of a sensing line having a conventional line width of 70 mu m and a length of 1 m is 200 OMEGA, the impedance at the other end may be 100 OMEGA or less. Under the same line width, length and line resistance conditions, the sensing line according to the present invention may have an impedance of 200 Ω at one end and an impedance of 180 Ω or more at the other end.

At this time, a 4 m sensing line may be needed to form a 5 inch touch window. The conventional sensing line has almost no impedance at a point about 2m long and can not recognize a pulse reflected at a point after 2m and can not recognize the touch. The sensing line according to the present invention can recognize a touch by recognizing the reflection pulse even at a position of about 10 m in length. Therefore, the sensing line according to the present invention can provide a touch window with improved reliability.

The second sensing pattern 102 formed in one unit cell UC is formed by a first sensing pattern 101 formed in the unit cell UC and a first sensing pattern 101 formed in a different unit cell UC It also serves as a connection. That is, the second sensing pattern 102 may be connected to one end and the other end of the first sensing pattern 101 formed in the unit cell UC. The second sensing pattern 102 connected to one end of the first sensing pattern 101 and the second sensing pattern 102 connected to the other end of the first sensing pattern 101 may extend in different directions.

At this time, the second sensing pattern 102 may be connected to the first sensing pattern 101 of another unit cell UC arranged in the first direction of the unit cell UC. The second sensing pattern 102 may be connected to a first sensing pattern 101 of another unit cell UC arranged in a second direction of the unit cell UC. That is, a second sensing pattern 102 extending in two different directions may be formed in one unit cell UC.

In detail, the second sensing pattern 102 may connect the unit cell UC to another unit cell UC tangential to the first direction. In addition, the second sensing pattern 102 may connect the unit cell UC with another unit cell UC tangential to the unit cell UC in the second direction.

Accordingly, the touch window according to the present invention includes a sensing line 100 including a plurality of unit patterns arranged in at least two different directions. The sensing line 100 may minimize a difference in length of patterns extending in different directions with respect to one node point. Thus, it is possible to prevent a sharp decrease in the impedance of the sensing line, reduce the noise of the impedance, and improve the touch sensitivity.

Hereinafter, a touch window according to the second embodiment will be described with reference to FIG. 5 is a view showing an effective area and a unit cell of the touch window according to the second embodiment. In the description of the touch window according to the second embodiment, description of parts similar to those of the touch window according to the above-described embodiment can be omitted.

Referring to FIG. 5, the touch window according to the embodiment includes a valid area AA in which a user can input a touch command. The effective area AA is divided into a plurality of unit cells UC.

The unit cell UC may be formed in a rectangular shape. At this time, the plurality of unit cells UC may be repeatedly arranged to extend in a first direction and a second direction different from the first direction. In this case, the first direction and the second direction may be perpendicular to each other.

A sensing line 200 is formed on the effective area AA. The sensing line 200 is sensed by a time domain reflection (TDR) measurement method and can recognize a touch position. A pulse generator to which a pulse is applied may be connected to one end of the sensing line 200, and the pulse is transmitted from one end of the sensing line 200 to the other end.

The sensing line includes a first sensing pattern 201 as a unit pattern formed in a plurality of unit cells UC and a second sensing pattern 202 as a pattern connecting unit patterns formed in different unit cells UC, . At this time, the first sensing pattern 201 and the second sensing pattern 202 may be integrally formed. Therefore, the sensing line 200 may be arranged to be filled in front of the effective area AA.

The first sensing pattern 201 may include a plurality of node points. The first pattern 201 may include four node points. The first sensing pattern 201 includes patterns extending in different directions with respect to the node point. For example, the first sensing pattern 201 may include a pattern of a letter-shaped pattern, and may include a pattern extending in the first direction and a pattern extending in the second direction with respect to one node point have.

At this time, the ratio of the length of the pattern extending in the first direction and the length of the pattern extending in the second direction with respect to one node point may be 1: 5 to 5: 1. Preferably, the ratio of the length of the pattern extending in the first direction to the length of the pattern extending in the second direction with respect to one node point may be 1: 2 to 2: 1. More preferably, the length of the pattern extending in the first direction with respect to one node point and the length of the pattern extending in the second direction may be substantially the same.

The sensing line 200 according to the present invention has a sensing line 200 having a sensing line 200 and a sensing line 200. The sensing line 200 includes a first sensing line 200 and a second sensing line 200, And the impedance difference at the other end can be reduced. Preferably, the difference in impedance per unit length of the sensing line 200 may be less than or equal to 40%. At this time, the unit length may be 1 m.

More specifically, when two arbitrary points of the sensing line 200 are selected within the unit length, the impedance of the point adjacent to the other end of the sensing line 200 may be formed to be smaller than the impedance of the point adjacent to the sensing line 200. At this time, the difference between the impedances of the two points is formed to be 40% or less of the impedance of the point adjacent to the one end. That is, the impedance of the point adjacent to the other end of the sensing line 200 within the unit length may be formed to be 60% or more of the impedance of the point adjacent to the one end.

Preferably, the difference in impedance per unit length of the sensing line 200 may be less than or equal to 20%. More preferably, the difference in impedance per unit length of the sensing line 200 may be less than or equal to 10%.

The second sensing pattern 202 formed on one unit cell UC is formed by forming a first sensing pattern 201 formed on the unit cell UC and a first sensing pattern 201 formed on the unit cell UC different from the first sensing pattern 201 formed on the unit cell UC It also serves as a connection. That is, the second sensing pattern 202 may be connected to one end and the other end of the first sensing pattern 201 formed in the unit cell UC.

At this time, the second sensing pattern 202 may be connected to the first sensing pattern 201 of another unit cell UC arranged in the first direction of the unit cell UC. The second sensing pattern 202 may be connected to a first sensing pattern 201 of another unit cell UC arranged in a second direction of the unit cell UC. That is, a second sensing pattern 202 extending in two different directions may be formed in one unit cell UC.

In detail, the second sensing pattern 202 may connect the unit cell UC to another unit cell UC tangential to the first direction. In addition, the second sensing pattern 202 may connect the unit cell UC with another unit cell UC tangential to the unit cell UC in the second direction.

Accordingly, the touch window according to the present invention includes a sensing line 200 including a plurality of unit patterns. The plurality of unit patterns are repeatedly arranged in the first direction and repeatedly arranged in the second direction at the same time. The unit patterns include patterns extending in different directions with respect to one node point, and the difference in length of patterns extending in different directions with respect to the node point can be minimized. Thus, it is possible to prevent a sharp decrease in the impedance of the sensing line, reduce the noise of the impedance, and improve the touch sensitivity.

Hereinafter, a touch window according to the third embodiment will be described with reference to FIG. 6 is a view showing an effective area and a unit cell of the touch window according to the third embodiment. In the description of the touch window according to the third embodiment, description of parts similar to those of the touch window according to the above-described embodiment can be omitted.

Referring to FIG. 6, the touch window according to the embodiment includes a valid area AA in which a user's touch command input is possible. The effective area AA is divided into a plurality of unit cells UC.

The unit cell UC may be formed in a rectangular shape. At this time, the plurality of unit cells UC may be repeatedly arranged to extend in a first direction and a second direction different from the first direction. In this case, the first direction and the second direction may be perpendicular to each other.

A sensing line 300 is formed on the effective area AA. A pulse may be applied to one end of the sensing line 300, and the pulse may progress from one end of the sensing line 300 to the other end.

The sensing line 300 includes a second sensing pattern 302 as a pattern connecting a first sensing pattern 301, which is a unit pattern formed in a plurality of unit cells UC, and a unit pattern formed in a different unit cell UC, . At this time, the first sensing pattern 301 and the second sensing pattern 302 may be integrally formed. Accordingly, the sensing line 300 may be arranged to be filled in front of the effective area AA.

The first sensing pattern 301 may include a plurality of node points. The first pattern 301 may include two node points. The first sensing pattern 301 includes patterns extending in different directions with respect to the node point. For example, the first sensing pattern 301 may include a z-shaped pattern, and may include a pattern extending in one direction with respect to one node point and a pattern extending in a direction different from the one direction .

At this time, the ratio of the length of the pattern extending in one direction and the length of the pattern extending in the other direction with respect to one node point may be 1: 5 to 5: 1. Preferably, the ratio of the length of the pattern extending in one direction to the length of the pattern extending in the other direction with respect to one node point may be 1: 2 to 2: 1. More preferably, the length of the pattern extending in one direction relative to one node point and the length of the pattern extending in the other direction may be substantially the same.

The second sensing pattern 302 formed on one unit cell UC is formed by forming a first sensing pattern 301 formed on the unit cell UC and a first sensing pattern 301 formed on the unit cell UC different from the first sensing pattern 301 formed on the unit cell UC It also serves as a connection. That is, the second sensing pattern 302 may be connected to one end and the other end of the first sensing pattern 301 formed in the unit cell UC.

The second sensing pattern 302 may be connected to a first sensing pattern 301 of another unit cell UC arranged in a first direction of the unit cell UC. The second sensing pattern 302 may be connected to a first sensing pattern 301 of another unit cell UC arranged in a second direction of the unit cell UC. That is, a second sensing pattern 302 extending in two different directions may be formed in one unit cell UC.

At this time, the second sensing patterns 302 may connect the unit cells UC spaced apart from the unit cells UC. The unit cell UC may be connected to another unit cell UC formed in contact with the unit cell UC. That is, any one of the second sensing patterns 302 extending in different directions may extend to another unit cell UC in contact with the unit cell UC, and the other may be separated from the unit cell UC The unit cells UC may be arranged to extend to another unit cell UC.

The sensing line 300 according to the present invention has a sensing line 300 having a sensing line 300 and a sensing line 300. The sensing line 300 includes a first sensing line 300 and a second sensing line 300, Can be reduced. Preferably, the difference in impedance per unit length of the sensing line 300 may be less than or equal to 40%. At this time, the unit length may be 1 m.

More specifically, when two arbitrary points of the sensing line 300 are selected within the unit length, the impedance of the point adjacent to the other end of the sensing line 300 may be smaller than the impedance of the point adjacent to the sensing line 300. At this time, the difference between the impedances of the two points is formed to be 40% or less of the impedance of the point adjacent to the one end. That is, the impedance of the point adjacent to the other end of the sensing line 300 within the unit length can be formed to be 60% or more of the impedance of the point adjacent to the one end.

Preferably, the difference in impedance per unit length of the sensing line 300 may be less than or equal to 20%. More preferably, the difference in impedance per unit length of the sensing line 300 may be less than or equal to 10%. Thus, it is possible to prevent a sharp decrease in the impedance of the sensing line, reduce the noise of the impedance, and improve the touch sensitivity.

Hereinafter, a touch window according to the fourth embodiment will be described with reference to FIG. FIG. 7 is a diagram showing an effective area and a unit cell of a touch window according to the fourth embodiment. In the description of the touch window according to the fourth embodiment, description of parts similar to those of the touch window according to the above-described embodiment can be omitted.

Referring to FIG. 7, the touch window according to the embodiment includes a valid area AA in which a user's touch command input is possible. The effective area AA is divided into a plurality of unit cells UC.

The unit cell UC may be formed in a rectangular shape. At this time, the plurality of unit cells UC may be repeatedly arranged to extend in a first direction and a second direction different from the first direction. In this case, the first direction and the second direction may be perpendicular to each other.

A sensing line 400 is formed on the effective area AA. A pulse may be applied to one end of the sensing line 400, and the pulse may proceed from one end of the sensing line 400 to the other end.

The sensing line includes a first sensing pattern 401 formed as a unit pattern in a plurality of unit cells UC and a second sensing pattern 402 as a pattern connecting unit patterns formed in different unit cells UC, . At this time, the first sensing pattern 401 and the second sensing pattern 402 may be integrally formed. Accordingly, the sensing line 400 may be disposed on the entire surface of the effective area AA.

The first sensing pattern 401 may include a plurality of node points. The first pattern 401 may include two node points. The first sensing pattern 401 includes patterns extending in different directions with respect to the node point. For example, the first sensing pattern 101 may include a u-shaped pattern, and may include a pattern extending in a first direction and a pattern extending in a second direction with respect to one node point .

At this time, the ratio of the length of the pattern extending in one direction and the length of the pattern extending in the other direction with respect to one node point may be 1: 5 to 5: 1. Preferably, the ratio of the length of the pattern extending in one direction to the length of the pattern extending in the other direction with respect to one node point may be 1: 2 to 2: 1. More preferably, the length of the pattern extending in one direction relative to one node point and the length of the pattern extending in the other direction may be substantially the same.

The second sensing pattern 402 may be connected to one end and the other end of the first sensing pattern 401 formed in the unit cell UC. The second sensing pattern 402 may be connected to a first sensing pattern 401 of another unit cell UC arranged in a first direction of the unit cell UC. The second sensing pattern 402 may be connected to the first sensing pattern 401 of another unit cell UC arranged in the second direction of the unit cell UC. That is, a second sensing pattern 402 extending in two different directions may be formed in one unit cell UC.

At this time, the second sensing pattern 402 may connect another unit cell (UC) formed apart from the unit cell (UC). Alternatively, another unit cell UC formed in contact with the unit cell UC may be connected. That is, it is sufficient that the second sensing pattern 402 connects the unit cell UC with another unit cell UC arranged in the first direction or the second direction in comparison with the unit cell UC, As shown in FIG.

The sensing line 400 according to the present invention has a sensing line 400 having a first sensing line 400 and a second sensing line 400 as the difference between the length of the pattern extending in the first direction and the length of the pattern extending in the second direction, And the impedance difference at the other end can be reduced.

Specifically, when two arbitrary points of the sensing line 400 are selected within the unit length, the impedance of the point adjacent to the other end of the sensing line 400 may be formed to be smaller than the impedance of the point adjacent to the sensing line 400. At this time, the difference between the impedances of the two points is formed to be 40% or less of the impedance of the point adjacent to the one end. That is, the impedance of the point adjacent to the other end of the sensing line 400 within the unit length may be formed to be 60% or more of the impedance of the point adjacent to the one end. The unit length may be 1m.

Preferably, the difference in impedance per unit length of the sensing line 400 may be less than or equal to 20%. More preferably, the difference in impedance per unit length of the sensing line 400 may be less than or equal to 10%. Thus, it is possible to prevent a sharp decrease in the impedance of the sensing line, reduce the noise of the impedance, and improve the touch sensitivity.

Hereinafter, a touch window according to the fifth embodiment will be described with reference to FIG. FIG. 8 is a view showing an effective area and a unit cell of the touch window according to the fifth embodiment. In the description of the touch window according to the fifth embodiment, description of parts similar to those of the touch window according to the above-described embodiment can be omitted.

Referring to FIG. 8, the touch window according to the embodiment includes a valid area AA in which a user can input a touch command. The effective area AA is divided into a plurality of unit cells UC.

The unit cell UC may be formed in a triangular shape. At this time, the plurality of unit cells UC may be repeatedly arranged to extend in the first direction, the second direction, and the third direction. In this case, the first direction to the third direction may be angles of 120 ° with respect to each other.

A sensing line 500 is formed on the effective area AA. A pulse may be applied to one end of the sensing line 500, and the pulse may proceed from one end of the sensing line 500 to the other end.

The sensing line 500 includes a second sensing pattern 502 that is a pattern connecting a first sensing pattern 501, which is a unit pattern formed in a plurality of unit cells UC, and a unit pattern formed in a different unit cell UC, . At this time, the first sensing pattern 501 and the second sensing pattern 502 may be integrally formed. Accordingly, the sensing line 500 may be arranged to be filled in front of the effective area AA.

The first sensing pattern 501 may include a plurality of node points. The first pattern 501 may include two node points. The first sensing pattern 501 includes patterns extending in different directions with respect to the node point. For example, the first sensing pattern 101 may include a pattern extending in one direction and a pattern extending in a different direction with respect to one node point.

At this time, the ratio of the length of the pattern extending in one direction and the length of the pattern extending in the other direction with respect to one node point may be 1: 5 to 5: 1. Preferably, the ratio of the length of the pattern extending in one direction to the length of the pattern extending in the other direction with respect to one node point may be 1: 2 to 2: 1. More preferably, the length of the pattern extending in one direction relative to one node point and the length of the pattern extending in the other direction may be substantially the same.

The second sensing pattern 502 may be connected to one end and the other end of the first sensing pattern 501 formed in the unit cell UC. The second sensing pattern 502 may be a first sensing pattern of another unit cell UC arranged in two directions selected from the group consisting of the first direction, the second direction and the third direction of the unit cell UC 501). That is, a second sensing pattern 502 extending in two different directions may be formed in one unit cell UC.

In detail, the second sensing pattern 502 may connect the unit cell UC with another unit cell UC that contacts the first direction and the second direction. Alternatively, the second sensing pattern 502 may connect the unit cell UC with another unit cell UC tangent to the first direction and the third direction. Alternatively, the second sensing pattern 502 may connect the unit cell UC with another unit cell UC that contacts the second direction and the third direction.

The sensing line 500 according to the present invention has a sensing line 500 and a sensing line 500. The sensing line 500 includes a sensing line 500 and a sensing line 500, Can be reduced.

Specifically, when two arbitrary points of the sensing line 500 are selected within a unit length, the difference between the impedances of the two points is formed to be 40% or less of the impedance of the point adjacent to the one end. That is, the impedance of the point adjacent to the other end of the sensing line 500 within the unit length may be formed to be 60% or more of the impedance of the point adjacent to the one end. The unit length may be 1m.

Preferably, the difference in impedance per unit length of the sensing line 500 may be 20% or less. More preferably, the difference in impedance per unit length of the sensing line 500 may be less than or equal to 10%. Thus, it is possible to prevent a sharp decrease in the impedance of the sensing line, reduce the noise of the impedance, and improve the touch sensitivity.

Hereinafter, a touch window according to the sixth embodiment will be described with reference to FIG. 9 is a view showing an effective area and a unit cell of the touch window according to the sixth embodiment. In the description of the touch window according to the sixth embodiment, the same parts as those of the touch window according to the above- The description of FIG.

Referring to FIG. 9, the touch window according to the embodiment includes a valid area AA in which a user can input a touch command. The effective area AA is divided into a plurality of unit cells UC. A sensing line 600 is formed on the effective area AA and a pulse applied to one end of the sensing line 600 proceeds to the other end of the sensing line 600.

It is sufficient that the plurality of unit cells UC include the same unit pattern, and may be formed in an irregular shape. That is, the unit cell UC includes a first sensing pattern 601, which is a unit pattern, and a second sensing pattern 602, which is a pattern that connects unit patterns formed in different unit cells UC. The first sensing pattern 601 and the second sensing pattern 602 may be integrally formed. Accordingly, the sensing line 600 may be disposed on the entire surface of the effective area AA.

The first sensing pattern 601 may include a plurality of node points. The first pattern 601 may include six node points. The first sensing pattern 601 includes patterns extending in different directions with respect to the one node point. For example, the first sensing pattern 101 may include a pattern extending in a first direction and a pattern extending in a second direction with respect to one node point. The first direction and the second direction may be perpendicular to each other.

At this time, the ratio of the length of the pattern extending in the first direction and the length of the pattern extending in the second direction with respect to one node point may be 1: 5 to 5: 1. Preferably, the ratio of the length of the pattern extending in the first direction to the length of the pattern extending in the second direction with respect to one node point may be 1: 2 to 2: 1. More preferably, the length of the pattern extending in the first direction with respect to one node point and the length of the pattern extending in the second direction may be substantially the same.

The second sensing pattern 602 may be connected to one end and the other end of the first sensing pattern 601 formed in the unit cell UC. The second sensing pattern 602 may be connected to the first sensing pattern 601 of another unit cell UC adjacent to the unit cell UC.

The sensing line 600 according to the present invention has a sensing line 600 having a first end and a second end of the sensing line 600 as the difference between the length of the pattern extending in the one direction and the length of the pattern extending in the other direction within the unit pattern is reduced, Can be reduced.

Specifically, when two arbitrary points of the sensing line 600 are selected within a unit length, the difference between the impedances of the two points is formed to be 40% or less of the impedance of the point adjacent to the one end. That is, the impedance of the point adjacent to the other end of the sensing line 600 within the unit length may be formed to be 60% or more of the impedance of the point adjacent to the one end. The unit length may be 1m.

Preferably, the difference in impedance per unit length of the sensing line 600 may be 20% or less. More preferably, the difference in impedance per unit length of the sensing line 600 may be less than or equal to 10%. Thus, it is possible to prevent a sharp decrease in the impedance of the sensing line, reduce the noise of the impedance, and improve the touch sensitivity.

The features, structures, effects and the like described in the foregoing embodiments are included in at least one embodiment of the present invention and are not necessarily limited to one embodiment. Further, the features, structures, effects, and the like illustrated in the embodiments may be combined or modified in other embodiments by those skilled in the art to which the embodiments belong. Therefore, it should be understood that the present invention is not limited to these combinations and modifications.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the present invention. It can be seen that various modifications and applications are possible. For example, each component specifically shown in the embodiments may be modified and implemented. It is to be understood that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof.

Claims (15)

A substrate including a valid region including a plurality of unit cells; And
And a sensing line disposed on the effective area of the substrate and sensing by a time domain measurement method,
When the sensing line selects any two points, the difference between the impedances of the two points is 40% or less of the impedance of one point,
A touch window having a sensing line length of 1 m between any two points. The method according to claim 1,
Wherein the plurality of unit cells are repeatedly arranged to extend in at least two different directions. The method according to claim 1,
A pulse is applied to one end of the sensing line,
The pulse advances to the other end of the sensing line,
And a reflection pulse reflected from the touch point is output from one end of the sensing line. The method according to claim 1,
Wherein one sensing line is formed in the effective area. The method according to claim 1,
Further comprising a circuit portion connected to one end of the sensing line,
Wherein the circuit unit comprises a pulse generator and a TDR measurement unit. A substrate including a valid region including a plurality of unit cells; And
And a sensing line disposed on the effective area of the substrate and sensing by a time domain measurement method,
Wherein the plurality of unit cells are repeatedly arranged to extend in at least two different directions. The method according to claim 6,
The unit cells are formed in a rectangular shape,
Wherein the plurality of unit cells are repeatedly arranged in a first direction and a second direction perpendicular to each other. The method according to claim 6,
Wherein the unit cells are formed in a triangular shape,
Wherein the plurality of unit cells are repeatedly arranged in a first direction, a second direction, and a third direction, which are at 120 degrees with respect to each other. The method according to claim 6,
The sensing line may include a first sensing pattern, which is a unit pattern formed in the unit cell; And
And a second sensing pattern that is a pattern connecting the first sensing patterns disposed in different unit cells. 10. The method of claim 9,
Wherein the first sensing pattern comprises a pattern extending in different directions with respect to a node point. 11. The method of claim 10,
Wherein a ratio of a length of a pattern extending in one direction and a length of a pattern extending in another direction based on a node point of the first sensing pattern is 1: 5 to 5: 1. 11. The method of claim 10,
Wherein a length of a pattern extending in one direction and a length of a pattern extending in another direction are the same with respect to a node point of the first sensing pattern. 10. The method of claim 9,
And the second sensing pattern is connected to one end and the other end of the first sensing pattern. 14. The method of claim 13,
Wherein a second sensing pattern connected to one end of the first sensing pattern and a second sensing pattern connected to the other end of the first sensing pattern extend in different directions. The method according to claim 6,
When the sensing line selects any two points, the difference between the impedances of the two points is 40% or less of the impedance of one point,
A touch window having a sensing line length of 1 m between any two points.

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