KR20090019881A - Capacitive touch panel and keypad-integrated telecommunication terminal equipment including the same - Google Patents

Abstract

One-bodied keypad type communications terminal equipment including the touch panel and the touch panel of the electrostatic capacitive type are provided to form the panel transparent electrode and keypad transparent electrode on the same substrate and to detect accurately the touched coordinate. The touch panel of the electrostatic capacitive type comprises transparent electrode layers (320,322) and controller(326). The transparent electrode layer is formed in one side of substrate. The transparent electrode layer is comprised of the first transparent electrode unit and the second transparent electrode part. The triangle form is materially connected to the first direction more than two at least In the first transparent electrode unit. The controller is bonded on the top of substrate. The controller controls the first direction coordinate and the touched backward.

Description

Capacitive Touch Panel and Keypad-Integrated Telecommunication Terminal Equipment Including the Same}

The present invention relates to a capacitive touch panel and a keypad integrated communication terminal including the same. Specifically, the panel transparent electrode layer and the keypad transparent electrode layer are formed in a specific pattern on a substantially same substrate, and the control unit is also substantially the same. The present invention relates to a capacitive touch panel formed by bonding an upper portion of a substrate and a keypad integrated communication terminal device including the same.

A personal computer, portable transmission device, or other personal information processing device performs text and graphic processing using various input devices such as a keyboard, a mouse, and a digitizer. These input devices have developed due to the necessity of using a keyboard and a mouse as an input device as an interface as a PC, and being able to input anybody with simpler and less misoperation, and to input characters by hand while carrying them. .

Nowadays, attention is shifting to more sophisticated technologies such as high reliability, the provision of new features, durability, and manufacturing techniques related to design and processing involving materials or materials, beyond meeting the needs associated with the general functions of these input devices. In particular, a touch panel is known as an input device which is simple, has less misoperation, can be input by anyone while carrying it, and can also input characters without other input devices.

However, inaccurate position detection has yet been made in such a touch panel, and in a communication terminal device having a touch panel and a keypad, the touch panel and the keypad must be configured as separate circuits, which leads to a complicated manufacturing process. .

Accordingly, the present invention has been made to solve the above-described problems, an object of the present invention is to form a panel transparent electrode layer and a keypad transparent electrode layer in a specific pattern on a substantially same substrate, and the control unit is also bonded on a substantially same substrate The present invention provides a capacitive touch panel and a keypad integrated communication terminal device including the same.

In order to achieve the above object, one side of the present invention is formed on a substrate, and one side of the substrate, the first transparent electrode portion and at least two substantially triangular shape is connected in the first direction and the first transparent electrode portion A transparent electrode layer comprising at least two substantially triangular shapes corresponding to each triangular shape and having at least two substantially triangular shapes connected to each other in a first direction, the transparent electrode layer being bonded to an upper portion of the substrate, And a controller configured to detect the first direction coordinates and the second direction coordinates to be touched, wherein the controller detects the first direction coordinates by the positions of the triangles of the first and second transparent electrode parts touched on the other side of the substrate. The area of the triangular shape of the first transparent electrode part touched on the other side of the substrate may be substantially square. Provides a touch panel of a capacitance type for detecting a second coordinate direction by a ratio of the area of the triangle and the second transparent electrode portion.

Another aspect of the invention corresponds to a substrate, a transparent electrode layer formed on one side of the substrate, each electrode pattern is formed for each pixel, and bonded to the substrate, the electrode pattern touched on the other side of the substrate It provides a capacitive touch panel including a control unit for detecting the coordinates of each pixel.

Preferably, the substrate may comprise glass, polyethylene resin or acrylic. The transparent electrode layer may include indium tin oxide or antimony tin oxide.

According to another aspect of the present invention, a first transparent electrode layer is formed on one side of the first substrate and the first substrate, and at least two or more first shape patterns are connected in a first direction to form at least two or more lines; A second substrate and at least two or more substantially second-shaped patterns formed on one side of the second substrate and meshing with the first-shaped pattern of the first transparent electrode layer to form a single pixel form a second direction. A second transparent electrode layer connected to the second transparent electrode layer having at least two lines formed thereon, bonded to an upper portion of the first substrate, and having a second direction coordinate touching the other side of the first substrate and touching the other side of the second substrate; And a control unit for detecting direction coordinates, respectively, wherein the control unit includes a line of the first transparent electrode layer touching the other side of the first substrate and a second transparent electrode layer touching the other side of the second substrate. A capacitive touch panel for detecting a second direction coordinate of the first transparent electrode layer and a first direction coordinate of the second transparent electrode layer at an intersection point of a line is provided.

Preferably, the pattern of the first shape may be substantially one triangle, and the pattern of the second shape may be one triangle that is substantially one pixel in engagement with one triangle that is the pattern of the first shape. The pattern of the first shape is two triangles substantially facing the vertices, and the pattern of the second shape is two triangles that engage with two triangles facing the vertex, which is the pattern of the first shape, to substantially form one pixel. It may be a triangle. The first and second substrates may include glass, polyethylene resin, or acrylic. The first and second transparent electrode layers may include indium tin oxide or antimony tin oxide.

According to another aspect of the present invention, a substrate is formed on one side of the substrate, and at least two or more substantially triangular shapes correspond to the respective triangular shapes of the first transparent electrode part and the first transparent electrode part connected in the first direction. And a panel transparent electrode layer formed of at least two substantially triangular shapes having a substantially rectangular shape and having a second transparent electrode portion connected in a first direction, and formed on one side of the same substrate as the panel transparent electrode layer, and having a predetermined key input. A keypad transparent electrode layer on which at least two key patterns are received, and a control unit configured to detect first and second direction coordinates of the panel transparent electrode layer touched on the other side of the substrate, and detect a key pattern of the keypad transparent electrode layer; The controller may include three first and second transparent electrode portions of the panel transparent electrode layer that are touched to the other side of the substrate. The area of the triangle of the first transparent electrode part which is detected by the position of the mold and touches the other side of the substrate, and the area of the triangle of the second transparent electrode part which is substantially rectangular in shape corresponding thereto. The present invention provides a keypad integrated communication terminal device including a capacitive touch panel that detects the second direction coordinate by a ratio of and detects a key pattern of a keypad transparent electrode layer touched on the other side of the substrate.

Another aspect of the present invention is formed on a substrate, a panel transparent electrode layer formed on one side of the substrate, each electrode pattern is formed for each pixel, and formed on one side of the same substrate as the panel transparent electrode layer, a predetermined key input A control unit for detecting the coordinates of each pixel corresponding to the electrode pattern of the panel transparent electrode layer touched on the other side of the substrate and the key transparent electrode layer having at least two key patterns receiving the key pattern, and detecting the key pattern of the keypad transparent electrode layer. Provided is a keypad integrated communication terminal device including a capacitive touch panel.

Preferably, the substrate may include a capacitive touch panel, characterized in that the glass, polyethylene resin or acrylic.

According to another aspect of the present invention, a first transparent electrode layer is formed on one side of the first substrate and the first substrate, and at least two or more first shape patterns are connected in a first direction to form at least two or more lines; A second substrate and at least two or more second shaped patterns formed on one side of the second substrate and meshing with the first shaped pattern of the first transparent electrode layer to form a single pixel are connected in a second direction. And a second transparent electrode layer having at least two lines formed thereon, a keypad transparent electrode layer formed on one side of the first substrate, and having at least two key patterns receiving a predetermined key input thereon, and on the other side of the first substrate. The second direction coordinates of the touched first transparent electrode layer and the first direction coordinates of the second transparent electrode layer touched on the other side of the second substrate are respectively detected, and the key pattern of the keypad transparent electrode layer is detected. The control unit may include a control unit, wherein the control unit is disposed at an intersection point of a line of the first transparent electrode layer touching the other side of the first substrate and a line of the second transparent electrode layer touching the other side of the second substrate. A capacitive touch panel that detects a second direction coordinate of the first transparent electrode layer and a first direction coordinate of the second transparent electrode layer, and detects a key pattern of the keypad transparent electrode layer touched on the other side of the first substrate. It provides a keypad integrated communication terminal device comprising a.

Preferably, the pattern of the first shape may be substantially one triangle, and the pattern of the second shape may be one triangle that is substantially one pixel in engagement with one triangle that is the pattern of the first shape. The pattern of the first shape is two triangles substantially facing the vertices, and the pattern of the second shape is two triangles that engage with two triangles facing the vertex, which is the pattern of the first shape, to substantially form one pixel. It may be a triangle. The first and second substrates may include glass, polyethylene resin, or acrylic. The controller may be bonded on the keypad transparent electrode layer. The keypad transparent electrode layer may include indium tin oxide or antimony tin oxide.

According to the present invention as described above, by forming a panel transparent electrode and a keypad transparent electrode in a specific pattern on the substantially same substrate, it is possible to accurately detect the coordinates touched, the control unit is also formed by bonding on the substantially same substrate It can work.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, embodiments of the present invention illustrated below may be modified in many different forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art.

1A schematically illustrates a cross-sectional structure of a capacitive touch panel of a single layer type according to the present invention.

Referring to FIG. 1A, a capacitive single layer touch panel includes a substrate 110 and a transparent electrode layer 120.

The substrate 110 includes a transparent material, and is preferably made of glass, polyethylene resin (PET), or acrylic.

The transparent electrode layer 120 is formed in a specific shape on one side of the substrate 110 and includes a transparent conductive material, preferably indium tin oxide (ITO) or antimony tin oxide (ATO). )

Here, when the other side of the substrate 110 is touched by a finger or another object, capacitance is induced between the substrate 110, which is an dielectric, and the transparent electrode layer 120. The controller (not shown) detects coordinates of positions touched on the other side of the substrate 110 through the induced change in capacitance. In addition, the controller is bonded to the upper portion of the substrate 110 in the form of Chip On Glass (COG). On the other hand, the permittivity of glass is 10ε ₀ {ε ₀ = 8.85 × 10 ^-12 (F / m)}, and the dielectric constant of acrylic is 5ε ₀ to 10ε ₀ .

Meanwhile, a protective film 130 attached to the transparent electrode layer 120 by the interlayer adhesive 135, for example, a PET film, a substrate protective film 140 protecting the substrate 110, and a scattering prevention film 145. It may further include.

In addition, the transparent electrode layer is used in the viewing area of the user, but in other areas, the resistance component of the circuit may be reduced by transparent electrode, metal wiring, metal plating, or silver coating.

1B schematically illustrates a cross-sectional structure of a dual layer capacitive touch panel according to the present invention.

The capacitive dual layer touch panel includes a first substrate 150, a first transparent electrode layer 155, a second substrate 160, a second transparent electrode layer 165, and a controller (not shown).

The first and second substrates 150, 160 comprise a transparent material, preferably made of glass, polyethylene resin or acrylic.

The first transparent electrode layer 155 is formed in a specific shape on one side of the first substrate 150 and includes a transparent conductive material, preferably made of indium tin oxide or antimony tin oxide. Here, when the other side of the first substrate 150 is touched by a finger or another object, capacitance is induced between the first substrate 150, which is a dielectric, and the first transparent electrode layer 155. The controller detects the second direction coordinates of the position touched on the other side of the first substrate 150 through the induced capacitance change.

The second transparent electrode layer 165 is formed in a specific shape on one side of the second substrate 160 and includes a transparent conductive material, preferably made of indium tin oxide or antimony tin oxide. Here, when the other side of the second substrate 160 is touched by a finger or another object, capacitance is induced between the second substrate 160, which is a dielectric, and the second transparent electrode layer 165. The controller detects the first direction coordinates of the position touched on the other side of the second substrate 150 through the induced capacitance change. As noted, the intersection of one line of the first transparent electrode layer 155 and one line of the second transparent electrode layer 165 corresponds substantially to one pixel in the touch panel.

The control unit is formed at the intersection of the line of the first transparent electrode layer 155 touching the other side of the first substrate 150 and the line of the second transparent electrode layer 165 touching the other side of the second substrate 160. Two-direction coordinates and a first direction coordinate are respectively detected. On the other hand, the controller is bonded on the substrate 110 in the form of a chip on glass.

Meanwhile, the first transparent electrode layer 155 is attached to the second substrate 160 by the first interlayer adhesive 170. The second transparent electrode layer 165 is attached to the protective film 180, such as a PET film, by the second interlayer adhesive 175. The substrate protection film 185 and the scattering prevention film 190 may be further included on the first substrate 150 to protect the first substrate 150.

In addition, the transparent electrode layer is used in the region visible to the user, but in other regions, the resistance component of the circuit may be reduced by transparent electrode, metal wiring, metal plating, or silver coating.

FIG. 2A is a plan view schematically illustrating a first embodiment of the touch panel of FIG. 1A.

The transparent electrode layers 210 and 212 of the single layer touch panel of the first embodiment may correspond to at least two or more substantially triangular first transparent electrode portions 210 and respective triangular shapes of the first transparent electrode portions 210. At least two substantially triangular second transparent electrode portions 212 having a triangular shape. As illustrated, five triangles aligned in the y-axis direction are respectively connected to the control unit 214 in the first transparent electrode unit 210, and five triangles aligned in the y-axis direction are connected to the second transparent electrode unit 212. Triangles are respectively connected to the controller 214. That is, the controller 214 detects the first direction coordinates, for example, the y-axis direction coordinates, by the positions of the triangles of the first transparent electrode unit 210 and the triangles of the second transparent electrode unit 212 that are touched through the substrate. In the second direction coordinates, for example, by the ratio of the area of the triangle of the first transparent electrode unit 210 touched through the substrate and the area of the triangle of the second transparent electrode unit 212 having a substantially rectangular shape corresponding to the area of the triangle. Detect the x-axis direction coordinates.

For example, when the resolution of 9 pixels is set in the x-axis direction and the point A is touched on the other side of the substrate, the area of the triangle of the first transparent electrode part 210 and the triangle of the second transparent electrode part 212 are set. Since the actual ratio of the area is 9: 1, the controller detects the touch of the substrate in the coordinates of the first pixel in the x-axis direction based on the lower left corner. In addition, the controller detects the touch of the substrate with the coordinates of the fifth pixel in the y-axis direction based on the lower left corner.

Meanwhile, the controller 214 is bonded to the upper portion of the substrate, and a flexible printed circuit board (FPCB) 216 is connected to the controller 214.

Therefore, the coordinates touched by the single layer, that is, the transparent electrode layers 210 and 212 through the substrate can be accurately detected.

FIG. 2B is a plan view schematically illustrating a second embodiment of the touch panel of FIG. 1A.

In the transparent electrode layer 220 of the single layer touch panel of the second embodiment, an electrode pattern is formed for each pixel.

The controller 222 is bonded on the substrate (not shown) and detects coordinates of pixels corresponding to the electrode patterns touched on the substrate.

The flexible printed circuit board 224 is connected to the controller 222.

FIG. 2C is a plan view schematically illustrating a third embodiment of the touch panel of FIG. 1B.

In the dual layer touch panel of the third embodiment, the first transparent electrode layer 230 is formed on one side of a first substrate (not shown), and at least two substantially triangular shapes are formed on the first transparent electrode layer 230. Directions, for example in the x-axis direction, to form at least two lines.

The second transparent electrode layer 232 is formed on one side of the second substrate (not shown), and the second transparent electrode layer 232 has at least two substantially triangular shapes corresponding to the respective triangular shapes of the first transparent electrode layer. The above substantially triangular shape is connected in a second direction, for example in the y-axis direction, to form at least two or more lines.

The controller (not shown) detects the second direction coordinates touching the other side of the first substrate and the first direction coordinates touching the other side of the second substrate, respectively. That is, the control unit of the first transparent electrode layer 230 at the intersection of the line of the first transparent electrode layer 230 touches the other side of the first substrate and the line of the second transparent electrode layer 232 touched the second substrate. The second direction coordinates, for example, the y-axis direction coordinates, and the first direction coordinates, for example, the x-axis direction coordinates of the second transparent electrode layer 232, are respectively detected. As noted, the intersection of one line of the first transparent electrode layer 155 and one line of the second transparent electrode layer 165 corresponds substantially to one pixel in the touch panel.

Specifically, when the A point of the first substrate and the second substrate is touched, the electrostatic at the intersection of the third line of the first transparent electrode layer 230 and the sixth line of the second transparent electrode layer 232 with respect to the lower left end. Since the capacitance changes, the control unit detects the coordinates of the A point as y-axis coordinates as 3 and detects the x-axis coordinates as 6.

The controller is connected to each line of the first transparent electrode layer 230 and each line of the second transparent electrode layer 232 through the flexible printed circuit board 234.

FIG. 2D is a plan view schematically illustrating a fourth embodiment of the touch panel of FIG. 1B.

In the dual layer touch panel of the fourth embodiment, the first transparent electrode layer 240 is formed on one side of a first substrate (not shown), and at least two triangles facing each vertex corresponding to one pixel It is connected in one direction to form at least two or more lines.

The second transparent electrode layer 242 is formed on one side of the second substrate (not shown), and the second transparent electrode layer 242 corresponds to two triangular shapes facing each vertex of the first transparent electrode layer 240. Thus, two triangles facing the vertices corresponding to one pixel, which are substantially rectangular in shape, are connected in at least two or more second directions to form at least two or more lines.

The controller (not shown) detects the second direction coordinates touching the other side of the first substrate and the first direction coordinates touching the other side of the second substrate, respectively. That is, the control unit may include the first transparent electrode layer (at the intersection of the line of the first transparent electrode layer 240 touching the other side of the first substrate and the line of the second transparent electrode layer 242 touching the other side of the second substrate ( The second direction coordinate of 240, for example, the y-axis coordinate, and the first direction coordinate of the second transparent electrode layer 242, for example, the x-axis direction, are respectively detected.

Specifically, when the point A of the first substrate and the second substrate is touched, the electrostatic at the intersection of the third line of the first transparent electrode layer 240 and the sixth line of the second transparent electrode layer 242 with respect to the lower left end. Since the capacitance changes, the control unit detects the coordinates of the A point as y-axis coordinates as 3 and detects the x-axis coordinates as 6.

The control unit is connected to each line of the first transparent electrode layer 240 and each line of the second transparent electrode layer 242 through the flexible printed circuit board 244.

FIG. 3A is a schematic plan view of the keypad integrated communication terminal device having the single layer capacitive touch panel of FIG. 2A.

The keypad integrated communication terminal device according to this embodiment includes a substrate (not shown), panel transparent electrode layers 310 and 312, a keypad transparent electrode layer 314, and a controller (not shown).

The panel transparent electrode layers 310 and 312 may include at least two substantially triangular shaped first transparent electrode portions 310 and at least two substantially substantially triangular shapes corresponding to respective triangular shapes of the first transparent electrode portions 310. The second transparent electrode part 312 of triangular shape is formed. As illustrated, five triangles aligned in the y-axis direction are respectively connected to the control unit through the first flexible printed circuit board 318 in the first transparent electrode part 310 and to the second transparent electrode part 312. Five triangles aligned in the y-axis direction are respectively connected to the controller through the first flexible printed circuit board 318. That is, the controller detects the first direction coordinates, for example, the y-axis direction coordinates, by the positions of the triangles of the first transparent electrode part 310 and the triangles of the second transparent electrode part 312 that are touched through the substrate. The second direction coordinates, for example, the x-axis direction, are determined by the ratio of the area of the triangle of the first transparent electrode part 310 touched through and the area of the triangle of the second transparent electrode part 312 having a substantially rectangular shape corresponding thereto. Detect coordinates. For example, when the resolution of 9 pixels is set in the x-axis direction and the point A is touched on the other side of the substrate, the area of the triangle of the first transparent electrode part 310 and the triangle of the second transparent electrode part 312 are set. Since the actual ratio of the area is 9: 1, the controller detects the touch of the substrate in the coordinates of the first pixel in the x-axis direction based on the lower left corner. In addition, the controller detects the touch of the substrate in the coordinates of the fifth pixel in the y-axis direction based on the lower left corner.

The keypad transparent electrode layer 314 is formed with a key pattern of various input keys including numeric keys and function keys. When a specific key pattern is touched, the controller detects the capacitance change of the corresponding keypad transparent electrode layer 314 through the second flexible printed circuit board 316.

Meanwhile, the keypad transparent electrode layer 314 may include indium tin oxide or antimony tin oxide.

3B is a schematic plan view of a keypad integrated communication terminal device according to another embodiment including the single layer type capacitive touch panel of FIG. 2A. Here, description substantially overlapping with the description of FIG. 3A will be omitted.

The keypad integrated communication terminal device including the dual layer capacitive touch panel of FIG. 1 includes panel transparent electrode layers 320 and 322, a keypad transparent electrode layer 324, a controller 326, and a flexible printed circuit board 328. .

Unlike the keypad integrated communication terminal having the single layer capacitive touch panel of FIG. 3A, the controller 326 is bonded to the panel transparent electrode layers 320 and 322 or the keypad transparent electrode layer 324.

Meanwhile, the keypad transparent electrode layer 324 may include indium tin oxide or antimony tin oxide.

FIG. 3C is a schematic plan view of the keypad integrated communication terminal device including the dual layer capacitive touch panel of FIG. 2C.

The keypad integrated communication terminal device of FIG. 1 includes a first transparent electrode layer 330, a second transparent electrode layer 332, a keypad transparent electrode layer 334, and a controller.

The first transparent electrode layer 330 is formed on one side of a first substrate (not shown), and at least two or more substantially triangular shapes are connected to the first transparent electrode layer 330 in a first direction, for example, in an x-axis direction. Two or more lines are formed.

The second transparent electrode layer 332 is formed on one side of the second substrate (not shown), and the second transparent electrode layer 332 has at least two substantially triangular shapes corresponding to the respective triangular shapes of the first transparent electrode layer. The above substantially triangular shape is connected in a second direction, for example in the y-axis direction, to form at least two or more lines.

The controller (not shown) detects the second direction coordinates touching the other side of the first substrate and the first direction coordinates touching the other side of the second substrate, respectively. That is, the control unit of the first transparent electrode layer 330 at the intersection of the line of the first transparent electrode layer 330 touches the other side of the first substrate and the line of the second transparent electrode layer 332 touched the second substrate. The second direction coordinates and the first direction coordinates of the second transparent electrode layer 332 are respectively detected.

The control unit is connected to each line of the first transparent electrode layer 330 and each line of the second transparent electrode layer 332 through the first flexible printed circuit board 338.

The keypad transparent electrode layer 334 is formed with key patterns of various input keys including numeric keys and function keys. When a specific key pattern is touched through the substrate, the controller detects the capacitance change of the corresponding keypad transparent electrode layer 334 through the second flexible printed circuit board 336.

The controller may be bonded to the first transparent electrode layer 330, the second transparent electrode layer 332, or the keypad transparent electrode layer 334.

Meanwhile, the keypad transparent electrode layer 334 may include indium tin oxide or antimony tin oxide.

FIG. 3D is a schematic plan view of the keypad integrated communication terminal device having the dual layer capacitive touch panel of FIG. 2D.

The keypad integrated communication terminal device according to the present embodiment includes a first transparent electrode layer 340, a second transparent electrode layer 342, a keypad transparent electrode layer 344, and a controller (not shown).

The first transparent electrode layer 340 is formed on one side of a first substrate (not shown), and two triangles facing each vertex corresponding to one pixel are connected in at least two or more first directions to form at least two or more lines. do.

The second transparent electrode layer 342 is formed on one side of the second substrate (not shown), and the second transparent electrode layer 342 corresponds to two triangular shapes facing each vertex of the first transparent electrode layer 340. Thus, two triangles facing the vertices corresponding to one pixel, which are substantially rectangular in shape, are connected in at least two or more second directions to form at least two or more lines.

The controller detects the second direction coordinates touching the other side of the first substrate and the first direction coordinates touching the other side of the second substrate, respectively. That is, the controller may include the first transparent electrode layer (at the intersection of the line of the first transparent electrode layer 340 touching the other side of the first substrate and the line of the second transparent electrode layer 342 touching the other side of the second substrate ( The second direction coordinates of 340 and the first direction coordinates of the second transparent electrode layer 342 are respectively detected.

The control unit is connected to each line of the first transparent electrode layer 340 and each line of the second transparent electrode layer 342 through the first flexible printed circuit board 348.

The keypad transparent electrode layer 344 is formed with key patterns of various input keys including numeric keys and function keys. When a specific key pattern is touched through the substrate, the controller detects the capacitance change of the corresponding keypad transparent electrode layer 344 through the second flexible printed circuit board 346.

The controller may be bonded to the first transparent electrode layer 340, the second transparent electrode layer 342, or the keypad transparent electrode layer 344.

Meanwhile, the keypad transparent electrode layer 344 may include indium tin oxide or antimony tin oxide.

Furthermore, the keypad integrated communication terminal device including the touch panel of FIG. 2B may be implemented. For example, the keypad integrated communication terminal device including the touch panel of FIG. 2B may be formed on a substrate, a panel transparent electrode layer formed on one side of the substrate and having an electrode pattern for each pixel, and on one side of the same substrate as the panel transparent electrode layer. Detects the coordinates of each pixel corresponding to the keypad transparent electrode layer having at least two key patterns receiving a predetermined key input, and the electrode pattern of the panel transparent electrode layer touched on the other side of the substrate, and detects the key pattern of the keypad transparent electrode layer It includes a control unit.

Although a preferred embodiment of the capacitive touch panel and the keypad integrated communication terminal device including the same according to the present invention have been described above, the present invention is not limited thereto, and the claims and the detailed description of the invention and the It is possible to carry out various modifications within the scope of the drawings and this also belongs to the present invention.

1A schematically illustrates a cross-sectional structure of a capacitive touch panel of a single layer type according to the present invention.

1B schematically illustrates a cross-sectional structure of a dual layer capacitive touch panel according to the present invention.

FIG. 2A is a plan view schematically illustrating a first embodiment of the touch panel of FIG. 1A.

FIG. 2B is a plan view schematically illustrating a second embodiment of the touch panel of FIG. 1A.

FIG. 2C is a plan view schematically illustrating a third embodiment of the touch panel of FIG. 1B.

FIG. 2D is a plan view schematically illustrating a fourth embodiment of the touch panel of FIG. 1B.

FIG. 3A is a schematic plan view of the keypad integrated communication terminal device having the single layer capacitive touch panel of FIG. 2A.

3B is a schematic plan view of a keypad integrated communication terminal device according to another embodiment including the single layer type capacitive touch panel of FIG. 2A.

FIG. 3C is a schematic plan view of the keypad integrated communication terminal device including the dual layer capacitive touch panel of FIG. 2C.

FIG. 3D is a schematic plan view of the keypad integrated communication terminal device having the dual layer capacitive touch panel of FIG. 2D.

Claims (18)

Substrate, At least two or more formed on one side of the substrate, the at least two substantially triangular shape is substantially rectangular in correspondence to the triangular shape of each of the first transparent electrode portion and the first transparent electrode portion connected in the first direction A transparent electrode layer composed of a second transparent electrode portion having a substantially triangular shape connected in a first direction, A control unit which is bonded to the upper substrate and detects first direction coordinates and second direction coordinates which touch the other side of the substrate, The controller detects the first direction coordinates by the positions of the triangles of the first and second transparent electrode portions touching the other side of the substrate, and the area of the triangles of the first transparent electrode portions touched on the other side of the substrate. And correspondingly detecting the second direction coordinates by a ratio of an area of a triangle of the second transparent electrode part corresponding to a substantially rectangular shape. Substrate, A transparent electrode layer formed on one side of the substrate and having electrode patterns formed for each pixel; And a control unit bonded to the substrate and detecting a coordinate of each pixel corresponding to the electrode pattern touched on the other side of the substrate. The method according to claim 1 and 2, The substrate is a capacitive touch panel, characterized in that the glass, polyethylene resin or acrylic. The method according to claim 1 and 2, The transparent electrode layer capacitive touch panel characterized in that it comprises indium tin oxide or antimony tin oxide. A first substrate, A first transparent electrode layer formed on one side of the first substrate and having at least two first shape patterns connected in a first direction to form at least two lines; A second substrate, At least two or more substantially second-shaped patterns formed on one side of the second substrate and engaged with the first-shaped pattern of the first transparent electrode layer to form a single pixel are connected to each other in at least two directions. 2nd transparent electrode layer in which the above line was formed, And a controller which is bonded to the first substrate and detects second direction coordinates touching the other side of the first substrate and first direction coordinates touching the other side of the second substrate. The control unit may further include a second direction of the first transparent electrode layer at an intersection point of the line of the first transparent electrode layer touching the other side of the first substrate and the line of the second transparent electrode layer touching the other side of the second substrate. A capacitive touch panel for detecting a coordinate and a first direction coordinate of the second transparent electrode layer. The method of claim 5, wherein The pattern of the first shape is substantially one triangle, and the pattern of the second shape is one triangle that forms a pixel substantially in engagement with one triangle that is the pattern of the first shape Touch panel. The method of claim 5, wherein The pattern of the first shape is two triangles substantially facing the vertices, and the pattern of the second shape is two triangles that engage with two triangles facing the vertex, which is the pattern of the first shape, to substantially form one pixel. Capacitive touch panel, characterized in that the triangular. The method of claim 5, wherein The first and second substrates are capacitive touch panel, characterized in that the glass, polyethylene resin or acrylic. The method of claim 5, wherein The first and second transparent electrode layer is capacitive touch panel, characterized in that containing indium tin oxide or antimony tin oxide. Substrate, At least two or more formed on one side of the substrate, the at least two substantially triangular shape is substantially rectangular in correspondence to the triangular shape of each of the first transparent electrode portion and the first transparent electrode portion connected in the first direction A panel transparent electrode layer composed of a second transparent electrode portion having a substantially triangular shape connected in a first direction, A keypad transparent electrode layer formed on one side of the same substrate as the panel transparent electrode layer and having at least two key patterns receiving a predetermined key input; And a controller configured to detect first and second directional coordinates of the panel transparent electrode layer touching the other side of the substrate, and detect a key pattern of the keypad transparent electrode layer. The controller detects the first direction coordinates by the positions of the triangles of the first and second transparent electrode portions of the panel transparent electrode layer touched on the other side of the substrate, and the first transparent electrode touched on the other side of the substrate. The key pattern of the keypad transparent electrode layer which detects the second direction coordinates by the ratio of the area of the negative triangle to the area of the triangle of the second transparent electrode part corresponding to the substantially rectangular shape, and touches the other side of the substrate. Keypad integrated communication terminal device comprising a capacitive touch panel for detecting the. Substrate, A panel transparent electrode layer formed on one side of the substrate and having electrode patterns formed for each pixel; A keypad transparent electrode layer formed on one side of the same substrate as the panel transparent electrode layer and having at least two key patterns receiving a predetermined key input; Keypad integrated communication including a capacitive touch panel including a control unit for detecting coordinates of each pixel corresponding to an electrode pattern of the panel transparent electrode layer touched on the other side of the substrate and detecting a key pattern of the keypad transparent electrode layer Terminal device. The method according to claim 10 and 11, The substrate is a keypad integrated communication terminal device comprising a capacitive touch panel, characterized in that the glass, polyethylene resin or acrylic. A first substrate, A first transparent electrode layer formed on one side of the first substrate and having at least two first shape patterns connected in a first direction to form at least two lines; A second substrate, At least two or more lines having at least two second shapes formed on one side of the second substrate and engaged with the first shape pattern of the first transparent electrode layer to form a single pixel are connected in a second direction. A second transparent electrode layer formed thereon, A keypad transparent electrode layer formed on one side of the first substrate and having at least two key patterns receiving a predetermined key input; The second direction coordinates of the first transparent electrode layer touched on the other side of the first substrate and the first direction coordinates of the second transparent electrode layer touched on the other side of the second substrate are respectively detected, and the key of the keypad transparent electrode layer is detected. Including a control unit for detecting a pattern, The controller may further include a second of the first transparent electrode layer at an intersection point of the line of the first transparent electrode layer touching the other side of the first substrate and the line of the second transparent electrode layer touching the other side of the second substrate. A keypad integrated communication terminal including a capacitive touch panel for detecting a direction coordinate and a first direction coordinate of the second transparent electrode layer and detecting a key pattern of the keypad transparent electrode layer touched on the other side of the first substrate. Device. The method of claim 13, The pattern of the first shape is substantially one triangle, and the pattern of the second shape is one triangle that forms a pixel substantially in engagement with one triangle that is the pattern of the first shape Keypad integrated communication terminal device including a touch panel of the type. The method of claim 13, The pattern of the first shape is two triangles substantially facing the vertices, and the pattern of the second shape is two triangles that engage with two triangles facing the vertex, which is the pattern of the first shape, to substantially form one pixel. Keypad integrated communication terminal device comprising a capacitive touch panel characterized in that the triangular. The method of claim 13, The first and the second substrate is a keypad integrated communication terminal device comprising a capacitive touch panel, characterized in that the glass, polyethylene resin or acrylic. The method according to claim 10, 11 or 13, The control unit is a keypad integrated communication terminal device comprising a capacitive touch panel, characterized in that bonded to the keypad transparent electrode layer. The method according to claim 10, 11 or 13, The keypad transparent electrode layer is a keypad integrated communication terminal device comprising a capacitive touch panel, characterized in that containing indium tin oxide or antimony tin oxide.

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