KR200253089Y1 - Structure of Electrode in Touch Screen - Google Patents

Abstract

The present invention relates to a resistive touch panel, and more particularly, to a method of adjusting a width of a potential compensation electrode according to a position to change a contact resistance value between a potential compensation electrode and a transparent electrode to compensate for potential distortion. It relates to an electrode structure. In addition, the width of the low-resistance potential compensation electrode increases as the distance from the signal application contact increases, increasing the contact resistance at the signal application contact and decreasing the contact resistance as it moves away from the signal application. It relates to an electrode structure of a touch panel that can be applied to a narrow area. It also relates to a flat panel display to which a touch panel is added.

The electrode structure of the touch panel of the present invention is arranged on the transparent electrode to form an active region through the interface, and one side of the potential compensation electrode formed of an asymmetrical width is narrower and the opposite width becomes larger, and arranged on the transparent electrode In order to change the contact resistance between the potential compensation electrode and the transparent electrode through the potential compensation electrode and the signal applying portion contacting the potential compensation electrode at an arbitrary position to apply an electrical signal to the potential compensation electrode. The side closer to the signal applying unit on the basis of the interface is characterized in that it is made of another boundary surface that forms an asymmetric width that becomes narrower and the width gradually increases as the distance. As a result, product reliability, applicability, design freedom, and mass production of the touch panel are improved.

Description

Structure of Electrode in Touch Panel {Structure of Electrode in Touch Screen}

The present invention relates to a resistive touch panel, and more particularly, to a method of adjusting a width of a potential compensation electrode according to a position to change a contact resistance value between a potential compensation electrode and a transparent electrode to compensate for potential distortion. It relates to an electrode structure. In addition, the width of the low-resistance potential compensation electrode increases as the distance from the signal application contact increases, increasing the contact resistance at the signal application contact and decreasing the contact resistance as it moves away from the signal application. It relates to an electrode structure of a touch panel that can be applied to a narrow area. It also relates to a flat panel display to which a touch panel is added.

In general, touch panels include resistive, capacitive, ultrasonic, optical sensor, and electromagnetic induction. Resistive film type is widely used as input device such as electronic organizer, PDA, portable PC in combination with LCD (Liquid Crystal Display), and design is more advantageous than other methods in thin, small size, light weight and low power consumption. There are metrics and analogs. Film substrate, glass substrate, plastic substrate, etc. are used as a transparent electrode material, and the combination is composed of upper and lower electrodes, and according to the wiring of the potential compensation electrode, the analog detection method is divided into 4 wire type, 5 wire type, and 8 wire type. .

The 4-wire resistive touch panel uses two substrates by forming transparent electrodes on the first substrate forming the upper electrode and the second substrate serving as the lower electrode, and forming dot spacers for electrical insulation between the 1.2 substrates. The signal distribution on the X and Y coordinates is calculated through the connector and sent to the external driver software.

In the case of the 4-wire resistive touch panel, the first substrate and the second substrate, and the first substrate and the second substrate are treated with an insulator, and the second substrate is a low resistance metal on both sides of the transparent conductive film after the insulating film process. In the axial direction, the X-axis potential compensation electrode is arranged in two lines so as to form an active area made of high resistance metal, and on the active area, an insulating dot spacer is formed between the substrates and the space between the X-axis potential compensation electrodes. It is formed in the active area. In contrast, the first substrate arranges the Y-axis potential compensation electrodes in two lines so as to form an active region of low resistance metal in the Y-axis direction on the transparent conductive film after the insulating film process on the substrate.

In operation, when a potential is applied to the first substrate to detect the X-axis coordinates, the potential is distributed over the entire surface of the transparent conductive film, and the upper and lower panels (1.2 substrates) are contacted by applying pressure to the touch panel (screen) with a finger or a pen. When the potential at that point is induced on the opposing second substrate, the X-axis coordinate is calculated using this signal, and the Y-axis coordinate is also detected on the second substrate while the upper and lower plates (1.2 substrate) are in contact with each other. Is applied to the front surface of the transparent conductive film, and the Y-axis potential at the point where the finger or the pen touches is induced on the first substrate, and the Y-axis coordinate is calculated by using this signal. The calculated X- and Y-axis values are shown on the display.

Meanwhile, the electrode structure applied to the conventional 4-wire resistive touch panel is shown in FIG. 1, and since the linearity of the electrode is related to signal distortion, it becomes one of important quality control items. In the structural arrangement of the electrodes 20, a low resistance metal is disposed on the transparent electrode 30, which is a high resistance metal, to form an equal electric field perpendicular to the signal application direction. 40a) and 40b are installed in parallel.

The electrode is inspected by measuring the degree of linearity of the electrode 20 in order to determine whether the completed touch panel works properly by stacking the upper substrate 10. The inspection method applies an operating voltage to the electrode 20 and measures the potential distribution actually distributed with the expected distribution potential on the transparent electrode 30 of the touch panel. If the measured value exceeds or falls short of a certain criterion, a location information error may be generated from the signal distortion. As a result, measuring the linearity degree of the electrode 20 is equivalent to inspecting good or bad of the touch panel.

2 illustrates a method of measuring electrode linearity on the substrate 10 for detecting the position in the X-axis direction as an example. Apply voltage (Vin) and ground at the ends of left and right X-axis potential compensation electrodes 40a and 40b as shown in the figure. In this case, an equal electric field perpendicular to the signal application direction is formed on the transparent electrode 30. In this case, when a point is touched by a pen, the upper substrate 10 is contacted through a contact resistance between the transparent electrode 30 of the upper substrate 10 and the transparent electrode 30 of the lower substrate 10 as shown in the figure. The potential of the point is transmitted to the lower substrate 10. In order to detect the potential induced on the lower substrate 10 again, the voltage across the sensing resistor RD provided between one end of the potential compensation electrodes 40a and 40b of the lower substrate 10 and the ground is measured as shown in the figure. . Then, a condition of RD >> RC is performed so that the potential of the contact point of the upper substrate 10 is almost mostly induced across the RD. The potential measured by the method of FIG. 2 as described above is shown in FIG. 3. Through this, the linearity error is obtained by comparing the ideal value and measured value and expressing the error as a percentage, and the value is obtained as follows.

When the potential at the X3 position of FIG. 2 is to be V3 of FIG. 3, when the measured potential at the X3 position is equal to the curve of the measured value of FIG. 3, an outlier at each point between Y1 and YN The difference between the (Ideal Value) and the measured value has an error VDIFF. In this way, the error VDIFF at each point is represented by the relative value of the ΔVX voltage between X1 and XN as a linearity error at that point, and this calculation method is similarly applied to the Y-axis direction.

An error caused by the degree of linearity of the electrode is an important criterion for screening the touch panel as good or bad since it causes the wrong position information when the position of the pen or the position information of the finger is displayed on the display. In other words, even if the product is designed to obtain small size, thinness and stable driving performance, the linearity of the electrode is directly related to the error of the position information, which is more important than other factors.

Therefore, judging the touch panel as good or defective by measuring the linearity of the electrode is equivalent to examining the electrical characteristics of the touch panel.

The electrical characteristics of the touch panel can be known from the electrical structure of the touch panel. 4 shows a method of forming a four-wire resistive electrode 20 using two kinds of metals, which are conductors. First, the transparent electrode 30, which is a high resistance metal, is formed in the form of a sheet with a predetermined thickness, and the potential compensation electrodes 40a, 40b, which are low resistance metal, are formed on the transparent electrode 30 in the form of a rod having a predetermined thickness and width. ) Form on the top.

When the electrical equivalent modeling of the structure according to the electrical characteristics is shown as shown in FIG. Here, the potential compensation electrodes 40a and 40b, which are low resistance metals, arrange the low resistance components in a line perpendicular to the signal application direction as shown in the figure, and the transparent electrode 30 which is the high resistance metal matrixes the resistance components as shown in the figure. Arrange in (Matrix) form to show sheet resistance. The potential compensation electrodes 40a and 40b and the transparent electrode 30 are electrically connected to each other by a contact resistance (RC) component. Theoretically, there should be no contact resistance between the transparent electrode 30 and the potential compensation electrodes 40a and 40b. However, when the potential distribution of the touch panel actually obtained through the process is measured, the contact resistance exists to affect the potential distribution. Go crazy.

This may be caused by the material difference between the original material of the potential compensation electrodes 40a and 40b and the material of the transparent electrode 30. Therefore, the cause should be approached based on more detailed physical analysis, but currently, it is designed to recognize the contact resistance.

As described above, the potential compensation electrodes 40a and 40b can grasp the problems and the disadvantages through the potential distribution by the linearity and the equivalent modeling of the electrode 20.

Assuming that a signal is applied to the touch panel, this is represented by an electrode equivalent circuit as shown in FIG. 6. In addition, the potentials distributed between P1 and PN in FIG. 6 are shown in FIG. 7 as potential distributions for each position.

In order to accurately grasp the position information, the potential distribution perpendicular to the signal application direction should be formed like the ideal potential, but when the potential is measured on the actual touch panel, the ideal potential and the measured potential match as shown in FIG. 7. The error ΔVd not distributed is distributed. Also, the farther away from the signal applying unit, the larger the error ((ΔVd) is) (it is known that the error increases).

In addition, this phenomenon is exacerbated by the margin between the touch panel and the display necessarily appearing when the touch panel is added to the flat panel display. For example, when the display is an LCD, a miniaturization and thinning design are required, and when a touch panel is added to these conditions, the electrode is placed in a narrow area, such as an LCD margin area (the area between the viewing area and the outer edge of the glass). Since the width of the electrode is reduced, this increases the resistance value in series, leading to an error in linearity of the electrode and causes a failure of the touch panel.

That is, since the resistance value of the potential compensation electrode, which is a low resistance metal, does not differ significantly from the resistance value of the transparent electrode, the potential distribution for each position appears as shown in FIG. 7.

In order to solve such a poor location-specific potential distribution, the resistance value of the potential compensation electrodes 40a and 40b should be smaller, and the width and thickness of the electrode should be adjusted in the direction of decreasing the resistance value. However, when designing a touch panel, there is a limit in the required characteristics of a touch panel used as an input device such as a display to increase the width and thickness indefinitely in order to reduce the resistance value of the potential compensation electrode.

Accordingly, an object of the present invention is to adjust the width of the potential compensation electrode of the resistive touch panel according to the position to change the contact resistance value between the potential compensation electrode and the transparent electrode and thereby compensate for the potential distortion.

Another object of the present invention is to provide a touch panel in which the width of the potential compensation electrode of the resistive touch panel is increased as the distance from the signal applying contact increases so that it cannot be applied to a narrow region without dislocation distortion.

Still another object of the present invention is to provide a touch panel additional flat panel display which compensates for signal distortion by maintaining linearity of the potential compensation electrode of the touch panel added to the flat panel display.

Features of the present invention for achieving this purpose,

On both sides of the transparent conductive film on the substrate, a low resistance metal is arranged in the X-axis direction so that the X-axis potential compensation electrode is made of an active area made of a high resistance metal, and on the active area, a dot spacer for electrical insulation between the two substrates is provided on the X-axis potential. The space between the compensation electrodes is formed in the active region, and the Y-axis potential compensation electrode is arranged to form an active region of low resistance metal in the Y-axis direction on the transparent conductive film on the other substrate. In the resistive touch panel,

The electrode structure of the touch panel is,

A potential compensation electrode arranged on the transparent electrode to form an active region through an interface and having an asymmetric width whose width is narrower on one side and larger on the other side;

A signal applying unit contacting the potential compensation electrode at an arbitrary position to apply an electrical signal to the potential compensation electrode arranged on the transparent electrode;

In order to change the contact resistance between the potential compensation electrode and the transparent electrode through the potential compensation electrode, an asymmetry in which the width closer to the signal applying part is narrower and the width gradually increases as the distance between the potential compensation electrode and the transparent electrode changes. It is characterized by consisting of another boundary surface forming a width.

In the arrangement of the electrodes of the resistive touch panel, the width of the potential compensation electrode can be adjusted according to the position to increase or decrease the contact resistance between the potential compensation electrode and the transparent electrode based on the signal applying unit. The signal distortion is reduced by compensating for the potential distortion, and an optimal touch panel applied to a narrow margin of the display unit without signal distortion can be realized.

1 is a conventional touch panel electrode structure

2 is a view for explaining the linearity measuring method of the touch panel electrode.

3 is a graph illustrating a determination method according to measuring linearity of a touch panel electrode.

4 is a diagram schematically showing a general electrode structure;

5 is a contact resistance equivalent circuit of a touch panel electrode.

6 is an equivalent circuit of a touch panel electrode

7 is a potential distribution of each electrode according to touch panel contact;

8 is an electrode structure of a touch panel according to the present invention

9 is another electrode structure of the touch panel according to the present invention

10 is a view showing another example of a touch panel electrode structure according to the present invention

11 is a view showing another example of a touch panel electrode structure according to the present invention

12 is a configuration example of a flat panel display with a touch panel according to the present invention

* Description of the symbols for the main parts of the drawings *

101a.101b: potential compensation electrode 102: transparent electrode

103: signal applying section 105.106: boundary surface

110: upper substrate 111: lower substrate

112.114: polarizing plate 113: liquid crystal display element

115: contact surface

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 8 to 12.

The present invention is applied to the electrode design of the resistive touch panel. The present invention also constitutes a flat panel display to which a touch panel is added.

The resistive touch panel is generally made of a substrate divided into upper and lower panels, and is put together.The X / Y-axis potential compensation electrodes, the transparent conductive film, the dot spacer, and the insulating film are arranged between them to read external signals transmitted to the panel. This is read through the controller and the external system and used as a system driving signal, and its configuration is symmetrically provided with an X-axis potential compensation electrode made of low resistance metal at random intervals to form a transparent conductive film made of an active region. The lower substrate bonded to the substrate and the lower substrate bonded to the lower substrate and provided with symmetrical Y-axis potential compensation electrodes made of low resistance metal at random intervals to form a transparent conductive film made of an active region are composed of the upper substrate bonded to the lower substrate. .

The electrode according to the present invention, as shown in Figure 8, is arranged on the transparent electrode 102 to form an active region a1 through the interface 105, one side is narrower (W1), the opposite width becomes larger ( W2) It is composed of the potential compensation electrodes 101a and 101b formed in the asymmetrical width W1 < W2.

In order to apply an electrical signal to the potential compensation electrodes 101a and 101b arranged on the transparent electrode 102, the signal applying unit 103 which contacts the potential compensation electrodes 101a and 101b is located at one side as shown in FIG. Or near the center. In this case, the potential compensation electrodes 101a and 101b each having an asymmetric width W1 <W2 may be symmetrically arranged on both sides with respect to the signal applying unit 103.

The signal applying unit based on the boundary surface 105 of the potential compensation electrodes 101a and 101b to change the contact resistance between the potential compensation electrodes and the transparent electrode 102 through the potential compensation electrodes 101a and 101b. The width closer to 103 is the width of an arbitrary width W1, and the width of the potential is gradually increased as the distance from the signal applying portion 103 becomes larger, so that the total potential compensation electrode 101a is designed. The widths of both longitudinal sides of 101b form an asymmetrical width W1 < W2.

The arrangement of the potential compensation electrodes 101a and 101b for changing the contact resistance between the potential compensation electrodes 101a and 101b and the transparent electrode 102 to compensate for the distortion of the potential, which is a linearity error, is performed by the transparent electrode 102 and the transparent electrode 102. It is arranged through the boundary surface 105 forming the active region a1 and the boundary surface 106 determined by the left and right asymmetric widths W1 < W2.

Here, the area of the signal applying unit 103 has an area of the arrangement area of the potential compensation electrodes 101a and 101b occupied on the transparent electrode 102 according to the asymmetric width W1 <W2 set based on the signal applying unit 103. The narrower and conversely, the gradually wider the characteristics.

In the arrangement of the potential compensation electrodes 101a and 101b, as the potential compensation electrode moves away from the signal applying unit 103, the curve of FIG. 8 is changed so that the contact area is changed so as to cancel the potential distortion by weighting according to the position. As shown in FIG. 9, as the contact area change between the signal applying unit 103 and the end becomes farther away from the signal applying unit, a straight type which is changed linearly without weighting according to the position may be selectively applied.

10 and 11 show a modified arrangement of the potential compensation electrodes 101a and 101b according to the position of the signal applying unit 103. The potential compensation electrodes 101a and 101b arranged here are unchanged in relation to the asymmetrical width W1 < W2 including the curve type and the straight type. However, the arrangement of the potential compensation electrodes shows an arrangement in which the potential compensation electrodes are bilaterally symmetrically bidirectionally based on the signal applying unit 103.

In this case, it is one of the designs that can be limitedly applied when the position of the signal applying unit 103 needs to be formed near the center rather than on one side.

In the electrode structure of the touch panel according to the present invention, as shown in FIG. 12, the compensation electrode region A2 is included in the LCD margin region A1 when applied to the touch panel additional flat panel display. The polarizer 112 is placed under the touch panel composed of the upper substrate 110 and the lower substrate 111, the liquid crystal display element 113 is placed under the polarizer, and the polarizer 114 is placed under the liquid crystal display element. In the case of a flat panel display in which a touch panel is laminated, the compensation electrode region A2 of the touch panel is arranged on the transparent electrode 102 as described above to form the active region a1 through the boundary surface 105, and one side of the touch panel has a width. The electrical signal is applied to the potential compensation electrodes 101a and 101b formed with the asymmetric widths W1 < W2 that are narrower and conversely larger, and to the potential compensation electrodes 101a and 101b arranged on the transparent electrode 102. Contact resistance value between the potential compensating electrodes 101a and 101b and the transparent electrode 102 through the signal applying unit 103 and the potential compensating electrodes 101a and 101b at an arbitrary position. Relative to the interface 105 of the potential compensation electrode Signal application section near side and 103 is made of another boundary surface (106) The more narrow and away form the asymmetric width (W1 <W2), the width increases gradually.

The shape of the electrode array of the touch panel according to the present invention in common serves to compensate for the potential distortion value generated in the process of identifying the position information.

When a signal is applied to the touch panel, the potential distributed between the touch panels is represented by an ideal potential and a measurement potential. To accurately grasp position information, a potential perpendicular to a signal application direction should be formed as in an ideal potential, but on an actual touch panel When the potential of is measured, this ideal / measurement potential is distributed, and the further the distance from the signal applying unit, the larger the error (see the potential distribution by position in FIG. 7).

This phenomenon has some other causes, but the resistance value of the potential compensation electrode, which is a low resistance metal, is not largely different from that of the transparent electrode. To solve this problem, the resistance value of the potential compensation electrode must be smaller and the resistance value is smaller. An alternative would be to adjust the width and thickness in the losing direction. However, when designing a touch panel, the width and thickness cannot be increased indefinitely in order to reduce the resistance value of the potential compensation electrode. In other words, the result is contrary to the design direction of the touch panel as an input device where thinness, light weight, and slimming are important. This phenomenon becomes more difficult to manage the resistance value of the potential compensation electrode when the touch panel is configured as an additional type or integrated type as a display.

In fact, in the present case of adding a touch panel as an LCD input device, the size of the touch panel is stacked beyond the LCD margin. This phenomenon is a visible result of the limitation in designing electrodes of a touch panel that is harmonized in a narrow area such as an LCD margin area, and consequently, the width of the electrode is smaller in order to harmoniously stack the touch panel on the LCD margin. As a phenomenon, the resistance value is increased, and the touch panel is accompanied with a linearity error of the electrode, causing a failure of the touch panel.

Therefore, the electrode design of the touch panel with sufficient LCD margin and no linearity error is so limited and its influence is directly related to the reliability of the position information.

As summarized above, first, when the touch panel is added as an input device to the display device, the application range of the touch panel is gradually decreasing. Reduction in LCD margins). Second, as the application width of the touch panel decreases, the probability of occurrence of poor linearity of the touch panel electrode increases. Third, the touch panel should not have a contact resistance component between the transparent electrode and the potential compensation electrode in theory, but in reality, it affects the potential distribution by the presence of the contact resistance. Fourth, in order to accurately grasp position information, a potential perpendicular to a signal application direction must be formed, such as an idle potential, but when a potential is measured on an actual touch panel, a curve curve is formed unlike an idle potential curve. Fifth, the location information error increases as the distance from the signal applying unit increases.

In the electrode according to the present invention, as shown in FIGS. 8 to 11, the potential compensating electrodes 101a and 101b arranged on the transparent electrode 102 are narrowed relative to the signal applying unit 103 and the signal applying unit is narrowed. As the distance from the 103 increases, the width is increased to form an asymmetric width W1 < W2 so that the width is arranged through the transparent electrode 102 and the boundary surface 105, 106, so that the potential compensation is performed in the signal applying unit 103. The contact area between the electrode and the transparent electrode is reduced to increase the contact resistance, and the contact area is decreased by increasing the contact area toward the end, and the contact resistance between the transparent electrode and the potential compensation electrode is the width of the potential compensation electrode. I can regulate it.

In order to compensate the potential by the potential distribution distortion measured as shown in FIG. 7, the contact resistance between the transparent electrode 102 and the potential compensation electrodes 101a and 101b is determined by the transparent electrode 102 and the potential compensation electrode 101a ( It is the same as adjusting the asymmetric width (W1 < W2) of 101b), so that the potential distribution between P1 and Pn in Fig. 6 can be distributed as the ideal potential of Fig. 7, which eliminates the linearity error of the electrode. .

In order to adjust the potential compensation electrodes 101a and 101b by adjusting the asymmetrical width W1 <W2, a method of dividing the potential compensation electrodes 101a and 101b into a continuous pattern shape and gradually increasing the width around the signal applying unit 103 may be applied. (FIGS. 8-11)

In the signal applying unit 103, the potential compensation electrodes 101a and 101b are formed to have an asymmetric width W1 < The potential compensation electrodes 101a and 101b can be arranged on the transparent electrode 102. When the signal applying unit 103 is located near the center, as shown in FIGS. By forming the potential compensation electrodes 101a and 101b designed to have an asymmetric width W1 < W2 that increases in width as a reference, the degree of freedom of design position of the signal applying unit 103 can be secured. The degree of freedom in electrode design is large.

An example of applying the present invention to an LCD which is one of flat panel displays as an input device may be configured as shown in FIG. 12. The polarizing plate 112 is placed under the touch panel including the upper substrate 110 and the lower substrate 112, and the liquid crystal display device 113 is placed under the polarizing plate 112, and the polarizing plate is below the liquid crystal display device 113. In a general stacking form in which the 114s are joined together and stacked, the compensation electrode region A2 of the touch panel can be placed in the LCD margin A1. In the past, the compensation electrode region exceeded the LCD margin in order to reduce the potential distortion by reducing the resistance value of the potential compensation electrode, but according to the electrode design of the present invention, it is not necessary to maintain the width and thickness of the potential compensation electrode sufficiently. Compensation electrode areas can be placed in the LCD margin.

As such, the present invention adjusts the width of the potential compensation electrode of the resistive touch panel according to the position based on the signal applying unit to change the contact resistance value between the potential compensation electrode and the transparent electrode, thereby compensating for the potential distortion. It has the effect of improving reliability. In addition, as the width of the potential compensation electrode increases away from the signal applying unit, there is an effect of providing a touch panel that cannot be applied to a narrow region without dislocation distortion. In addition, the present invention has the effect of designing a reliable touch panel additional flat panel display that compensates for signal distortion by maintaining the linearity of the potential compensation electrode of the touch panel added to the flat panel display.

Claims (5)

On both sides of the transparent conductive film on the substrate, a low resistance metal is arranged in the X-axis direction so that the X-axis potential compensation electrode is made of an active area made of a high resistance metal, and on the active area, a dot spacer for electrical insulation between the two substrates is provided on the X-axis potential The space between the compensation electrodes is formed in the active region, and the Y-axis potential compensation electrode is arranged to form an active region of low resistance metal in the Y-axis direction on the transparent conductive film on another substrate. In the resistive touch panel, The electrode structure of the touch panel is, A potential compensation electrode arranged on the transparent electrode to form an active region through an interface and having an asymmetric width whose width is narrower on one side and larger on the other side; A signal applying unit contacting the potential compensation electrode at an arbitrary position to apply an electrical signal to the potential compensation electrode arranged on the transparent electrode; In order to change the contact resistance between the potential compensation electrode and the transparent electrode through the potential compensation electrode, an asymmetry in which the width closer to the signal applying part is narrower and the width gradually increases as the distance between the potential compensation electrode and the transparent electrode changes. An electrode structure of a touch panel, characterized by comprising another interface forming a width. The method of claim 1, When the signal applying portion for applying an electrical signal to the potential compensation electrode arranged on the transparent electrode is located near the center portion, the potential compensation electrode having an asymmetric width W1 <W2 is symmetrically arranged on both sides of the signal applying portion. The electrode structure of the touch panel characterized by the above-mentioned. The method of claim 1, The arrangement of the potential compensation electrode is an electrode structure of the touch panel, characterized in that arranged on the transparent electrode through the boundary surface formed by the boundary between the transparent electrode and the active region and the asymmetric width (W1 <W2). The method of claim 1, And the potential compensation electrode has a curved shape in which a contact area is changed to offset potential distortion by being weighted according to a position as it moves away from the signal applying unit. The method of claim 1, The potential compensation electrode is a touch panel electrode structure, characterized in that the change in the contact area between the signal applying portion and the end is linearly changed as the distance away from the signal applying portion.