KR20150125344A - Touch panel - Google Patents

Abstract

Disclosed is a touch panel having a single layer structure. The touch panel includes a plurality of sensing blocks extending in a column direction and arranged in a row direction. Each of the sensing blocks includes a right-driving line and a sensing line. The right-driving line includes a plurality of right-driving electrodes arranged in a column direction. The sensing line includes a plurality of sensing electrodes arranged in a column direction and horizontally disposed with the right-driving electrodes. Each of the right-driving electrodes is orthogonally projected to two or more sensing electrodes. Accordingly, two sensing electrodes correspond to one driving electrode, so the number of connection wires needed in connecting driving electrodes can be reduced. Moreover, a plurality of sensing electrodes correspond to one driving electrode, so time spent in scanning an overall touch panel can be reduced.

Description

TOUCH PANEL {TOUCH PANEL}

The present invention relates to a touch panel, and more particularly, to a touch panel having a single-layer structure.

As the kinds of electronic devices to be encountered in everyday life are gradually diversified and the function of each electronic device becomes more sophisticated and complicated, there is a need for a user interface that can be easily learned and intuitively operated by the user. A touch sensing device has been attracting attention as an input device capable of satisfying such a requirement and has already been widely applied to various electronic devices.

A touch sensing device for recognizing a screen touch or a gesture of a user as input information is classified into a resistance film type, a capacitive type, an ultrasonic type, and an infrared type depending on the operation type of the touch sensing device. The capacity method is attracting much attention because it is easy to input multi-touch.

In such a capacitance type touch panel, it is important to structure the touch panel to more accurately detect the change in capacitance. The touch panel may have a two-layer structure, wherein the touch sensor includes a plurality of drive electrode traces intersecting a plurality of sensing electrode traces (e.g., traces extending in the X-axis direction) Y-axis direction traces), and the drive and sensing electrode traces are separated by a dielectric material such as PET, glass, or the like.

However, the touch panel, which includes the drive and sensing electrode traces, respectively formed in the lower and upper layers of the two-layer structure, can be expensive to manufacture and can be thickened. This is due to the process and structure of bonding the electrode layers of the two-layer structure.

Accordingly, a touch panel having coplanar single layer touch sensors fabricated on a single side of a single layer of a substrate of a touch panel has been proposed.

On the other hand, if there are many wires in the single layer touch sensor, it is difficult to find linearity and accuracy in touch due to an increase in dead zone which operates in a touch-free area. In the case of a single layer touch panel, the driving electrodes arranged in the column direction and the sensing electrodes adjacent to the driving electrodes are arranged.

As the number of sensing electrodes increases, the number of connection wirings connected to the sensing electrodes and connecting to the external touch recognition chip also increases. If the number of the connection wirings increases, the area where the connection wirings are formed between the sensing electrodes arranged in the row direction and the driving electrodes adjacent to the sensing electrodes increases, thereby increasing the dead zone. Further, if the number of connection wirings increases, the number of pads of the touch recognition chip also increases.

Korean Registered Patent No. 10-0885730 (registered date: February 19, 2009) Korea Patent Publication No. 2010-0083012 (Published on July 21, 2010) Korean Registered Patent No. 10-1169250 (registered on July 23, 2012) Korean Public Patent No. 2012-0094982 (public date: August 28, 2012) Korean Laid-Open Patent Application No. 2013-0035833 (Publication Date: April 9, 2013) Korean Registered Patent No. 10-1293165 (registered on Aug. 6, 2013)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a touch panel of a single layer structure.

In order to realize the object of the present invention, the touch panel according to an embodiment includes a plurality of sensing blocks extending in a column direction and arranged in a row direction. Each of the sensing blocks includes a right-driving line and a sensing line. The right-driving line includes a plurality of right-driving electrodes arranged in the column direction. The sensing line includes a plurality of sensing electrodes arranged in the column direction and arranged in parallel with the right-driving electrodes. Here, each of the right-driving electrodes is orthogonally projected onto two or more sensing electrodes.

In one embodiment, the right-driving electrodes and the sensing electrodes may be formed in the same layer.

In one embodiment, each of the sensing electrodes orthogonal to the same right-driving electrode may be coupled to a different sensing pad.

In one embodiment, each of the two sensing electrodes may be electrically isolated.

In one embodiment, each of the right-driving electrodes and the sensing electrodes may have a triangular tooth shape, and the right-driving electrodes and the sensing electrodes may be arranged in a coupling manner.

In one embodiment, each of the sensing electrodes may have a triangular shape, and each of the right-driving electrodes may have a triangular shape connected thereto.

In one embodiment, each of the sensing blocks may have a strip shape.

In one embodiment, the region between the drive line and the sensing line may have a zigzag shape.

In one embodiment, the right-driving electrodes disposed in the same row line among the right-driving electrodes disposed in the sensing blocks may receive the same driving voltage.

In one embodiment, each of the sensing blocks may further include a left-driving line including a plurality of left-driving electrodes.

In one embodiment, the left-driving electrodes, the right-driving electrodes, and the sensing electrodes may be formed in the same layer.

According to such a touch panel, since two sensing electrodes correspond to one driving electrode, the number of connection wirings necessary for connecting the driving electrodes can be reduced. In addition, since the plurality of sensing electrodes correspond to one driving electrode, the time required for scanning the entire touch panel can be reduced.

1 is a plan view for explaining a touch panel according to an embodiment of the present invention.
2 is a waveform diagram for explaining driving of the touch panel shown in Fig.
3 is a table for explaining that the sensing signals detected in the touch panel shown in FIG. 1 are mapped to a memory.
4 is a plan view illustrating a touch panel according to another embodiment of the present invention.
5 is a plan view for explaining a touch panel according to another embodiment of the present invention.
6 is a plan view illustrating a touch panel according to still another embodiment of the present invention.
FIG. 7 is a table for explaining how the sensing signals detected in the touch panel shown in FIG. 6 are mapped to a memory.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in more detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for like elements in describing each drawing. In the accompanying drawings, the dimensions of the structures are enlarged to illustrate the present invention in order to clarify the present invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a part or a combination thereof is described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Also, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

In the following, the terms left side or right side refers to viewing at the observer's point of view of the drawing. Further, the term column direction means downward direction, and the term row direction means rightward direction.

1 is a plan view for explaining a touch panel according to an embodiment of the present invention.

Referring to FIG. 1, the touch panel 100 includes a first sensing block SB1, a second sensing block SB2, a third sensing block SB3, and a fourth sensing block SB4 ). In this embodiment, for convenience of explanation, a touch panel having four sensing blocks disposed therein is shown.

Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 extends in the column direction (or the Y axis direction) (Or X-axis direction). Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 has a strip shape.

The first sensing block SB1 includes a right-driving line 110, a sensing line 120, a plurality of right-driving connection lines 130, and a plurality of sensing connection lines 140. The right-driving line 110, the sensing line 120, the right-driving connection lines 130, and the sensing connection lines 140 are formed in the same layer. The region between the right-driving line 110 and the sensing line 120 has a zigzag shape.

The right-driving line 110 includes a plurality of right-driving electrodes 112 arranged in the column direction, and is disposed in the right area of the first sensing block SB1. In this embodiment, the number of the right-driving electrodes 112 is five. In this embodiment, the size of each of the right-driving electrodes 112 is equal to each other. Each of the right-driving electrodes 112 has a W-shape corresponding to a region adjacent to the sensing line 120.

The sensing line 120 includes a plurality of sensing electrodes arranged in the column direction and is disposed in the left region of the first sensing block SB1 adjacent to the right driving line 110. [ In this embodiment, the number of the sensing electrodes is ten. In this embodiment, odd-numbered sensing electrodes are connected to each other in a cascade manner, and even-numbered sensing electrodes are connected to each other in a cascade manner.

In the present embodiment, the sensing line 120 includes a plurality of first sensing electrodes 122 for sensing first sensing signals, a plurality of second sensing electrodes 124 for sensing second sensing signals, First connection lines 126 connecting the first sensing electrodes 122 connected to each other and second connection lines 128 connecting the second sensing electrodes 124 adjacent to each other. When viewed on a plane, each of the first sensing electrodes 122 and the second sensing electrodes 124 has a triangular shape. The first connection wiring 126 has a shape that surrounds two hypotenuses of the second sensing electrode 124 and the second connection wiring 128 has a shape that surrounds the base of the first sensing electrode 122 Shape.

In this embodiment, each of the right-driving electrodes 112 has a triangular tooth shape, and each of the first and second sensing electrodes 122 and 124 has a triangular tooth shape. Accordingly, the right-driving electrodes 112 and the first and second sensing electrodes 122 and 124 are arranged in a coupling shape.

In this embodiment, each of the first and second sensing electrodes 122 and 124 has a triangular shape, and each of the right-driving electrodes 112 has a triangular shape connected thereto.

In this embodiment, the right-drive electrode disposed on the same row line among the right-drive electrodes 112 disposed in the sensing blocks receives the same right-drive voltage.

In this embodiment, two sensing electrodes are disposed adjacent to one driving electrode, but three or more sensing electrodes may be disposed adjacent to one driving electrode.

The right-driving connection lines 130 are connected to the right-driving electrodes 112, respectively. In one example, the line widths of the right-drive interconnections 130 may be equal to each other. In another example, the line width of each of the right-drive interconnections 130 may gradually increase from the observer's point toward the bottom. In another example, the line width of each of the right-drive interconnections 130 may increase stepwise from the observer's point toward the bottom.

The sensing connection lines 140 include a first sensing connection line connecting the first sensing electrode and one sensing pad and a second sensing connection line connecting the second sensing electrode and the other sensing pad. In this embodiment, the first sensing electrode of the first sensing block SB1 is connected to the second sensing pad RX1 through an external wiring formed in the peripheral region of the touch panel 200, And is connected to the first sensing pad RX1 through an external wiring formed in a peripheral region of the panel 200. [ The first sensing electrode of the second sensing block SB2 is connected to the fourth sensing pad RX4 through the external wiring formed in the peripheral region of the touch panel 200 and the second sensing electrode is connected to the periphery of the touch panel 200 And is connected to the third sensing pad RX3 through the external wiring formed in the region. The first sensing electrode of the third sensing block SB3 is connected to the sixth sensing pad RX6 through an external wiring formed in a peripheral region of the touch panel 200, And is connected to the fifth sensing pad RX5 through an external wiring formed in the peripheral region. The first sensing electrode of the fourth sensing block SB4 is connected to the eighth sensing pad RX8 through an external wiring formed in a peripheral region of the touch panel 200, And connected to the seventh sensing pad RX7 through an external wiring formed in the peripheral region.

As described above, according to the present embodiment, each of the sensing blocks extending in the column direction and arranged in the row direction includes a right-driving line and a sensing line arranged in parallel to the right-driving line , One right-driving electrode orthogonal to the sensing line covers two or more sensing electrodes, and each of the two or more sensing electrodes is electrically isolated.

Therefore, since two sensing electrodes correspond to one right-driving electrode, the number of connection wirings necessary for connecting the right-driving electrode and the driving pad can be reduced and the number of driving pads can be reduced.

In addition, since the plurality of sensing electrodes correspond to one right-driving electrode, the time required for scanning the entire touch panel can be reduced.

2 is a waveform diagram for explaining driving of the touch panel shown in Fig. 3 is a table for explaining that the sensing signals detected in the touch panel shown in FIG. 1 are mapped to a memory.

1 to 3, driving signals from an external capacitance sensing circuit (not shown) are supplied to the driving lines through the first to fifth driving pads TX1, TX2, ..., TX5 The driving electrodes are sequentially applied.

The driving signals applied to the driving electrodes are detected by the first sensing electrodes and the second sensing electrodes of the sensing lines, respectively, and the detected signals are defined as sensing signals, RX1, RX2, ..., RX7, RX8 to the capacitive sensing circuit.

The capacitance sensing circuit calculates touch coordinates based on the sensing signals. For example, the sensing signals may be mapped to a memory (not shown) as shown in FIG. 3 and used for touch coordinate recognition.

When a touch is generated at a specific position, the voltage level of the sensing signal detected at the sensing electrode corresponding to the position may be relatively low. Therefore, the position corresponding to the sensing electrode corresponding to the relatively low voltage level can be recognized as the touch coordinates.

4 is a plan view illustrating a touch panel according to another embodiment of the present invention.

4, a touch panel 200 according to another embodiment of the present invention includes a first sensing block SB1, a second sensing block SB2, a third sensing block SB3, and a fourth sensing block SB4 ). In this embodiment, for convenience of explanation, a touch panel having four sensing blocks disposed therein is shown.

Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 extends in the column direction (or the Y axis direction) Or X-axis direction). Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 has a strip shape.

The first sensing block SB1 includes a right driving line 210, a left driving line 220, a sensing line 230, a plurality of right driving connecting lines 240, (250) and a plurality of sensing connection wires (260). Driving connection lines 240, the left-driving connection lines 250, and the sensing connection 230. The right-driving line 210, the left-driving line 220, the sensing line 230, Wirings 260 are formed in the same layer. The area between the right-driving line 210 and the sensing line 230 has a zigzag shape. The area between the left-hand driving line 220 and the sensing line 230 has a zigzag shape.

The right-driving line 210 includes a plurality of right-driving electrodes 212 arranged in the column direction, and is disposed in the right area of the first sensing block SB1. In this embodiment, the number of the right-driving electrodes 212 is five. In this embodiment, the size of each of the right-driving electrodes 212 is equal to each other. Each of the right-driving electrodes 212 has a W-shape corresponding to a region adjacent to the sensing line 230.

The left-driving line 220 includes a plurality of left-driving electrodes 222 arranged in a column direction, and is disposed in the left area of the first sensing block SB1. In this embodiment, the number of the left-driving electrodes 222 is five. In this embodiment, the size of each of the left-driving electrodes 222 is equal to each other. Each of the left-driving electrodes 222 has a W-shape corresponding to a region adjacent to the sensing line 230.

The sensing line 230 includes a plurality of sensing electrodes arranged in a column direction and is disposed between the right-driving line 210 and the left-driving line 220.

In the present embodiment, the sensing line 230 includes a plurality of first sensing electrodes 232 for sensing first sensing signals, a plurality of second sensing electrodes 234 for sensing second sensing signals, And a plurality of third sensing electrodes 236 sensing one sensing signals. Here, one first sensing electrode 232, one second sensing electrode 234, and one third sensing electrode 236 correspond to one right-driving electrode. The sensing line 230 may include first connection lines 237 for cascade-connecting the first sensing electrodes 232, second connection lines 237 for connecting the second sensing electrodes 234 in a cascade manner, And third connection wirings 239 connecting the connection wirings 238 and the third sensing electrodes 236 in a cascade manner.

Each of the first sensing electrodes 232 and the third sensing electrodes 236 has a triangular shape and each of the second sensing electrodes 234 has a rhombic shape. The first connection wiring 237 has a shape that surrounds two sides of the second sensing electrode 234 and the second connection wiring 228 has a shape that surrounds two sides of the second sensing electrode 234, 2 sensing electrode 234 of the first embodiment. Accordingly, the first sensing electrodes 232 and the third sensing electrodes 236 are mirror-symmetrical with respect to the third connection wiring lines 239. Further, the right-driving electrodes of the right-driving line and the left-driving lines of the left-driving line are symmetrical with respect to the third connecting lines 239.

In this embodiment, each of the right-driving electrodes 212 has a triangular tooth shape, and each of the first and second sensing electrodes 232 and 234 has a triangular tooth shape. Accordingly, the right-driving electrodes 212 and the first and second sensing electrodes 232 and 234 are arranged in a coupling shape.

In this embodiment, each of the left-driving electrodes 222 has a triangular tooth shape, and each of the second and third sensing electrodes 234 and 236 has a triangular tooth shape. Accordingly, the left-driving electrodes 222 and the second and third sensing electrodes 234 and 236 are arranged in a coupling shape.

In this embodiment, among the driving electrodes 212 disposed in the first through fourth sensing blocks SB1, SB2, SB3, and SB4, the driving electrodes disposed on the same row line receive the same driving voltage.

The right-driving connection lines 240 are connected to the right-driving electrodes 212, respectively. In one example, the line widths of each of the right-drive interconnections 240 may be equal to each other. In another example, the line width of each of the right-drive interconnections 240 may gradually increase from the observer's point toward the bottom. In another example, the line width of each of the right-drive interconnections 240 may increase stepwise from the observer's point toward the bottom.

The left-driving connection lines 250 are connected to the left-driving electrodes 222, respectively. In one example, the line widths of the left-driving connecting lines 250 may be equal to each other. In another example, the line width of each of the left-driving connecting lines 250 may gradually increase from the observer's point toward the bottom. In another example, the line width of each of the left-driving connecting lines 250 may increase stepwise from the observer's point toward the bottom.

The sensing connection wirings 260 include a first sensing connection wiring connecting the first sensing electrode and one sensing pad and a second sensing connection wiring connecting the second sensing electrode and the other sensing pad.

In this embodiment, the first sensing electrode of the first sensing block SB1 is connected to the second sensing pad RX1 through an external wiring formed in the peripheral region of the touch panel 200, And is connected to the first sensing pad RX1 through an external wiring formed in a peripheral region of the panel 200. [ The first sensing electrode of the second sensing block SB2 is connected to the fourth sensing pad RX4 through the external wiring formed in the peripheral region of the touch panel 200 and the second sensing electrode is connected to the periphery of the touch panel 200 And is connected to the third sensing pad RX3 through the external wiring formed in the region. The first sensing electrode of the third sensing block SB3 is connected to the sixth sensing pad RX6 through an external wiring formed in a peripheral region of the touch panel 200, And is connected to the fifth sensing pad RX5 through an external wiring formed in the peripheral region. The first sensing electrode of the fourth sensing block SB4 is connected to the eighth sensing pad RX8 through an external wiring formed in a peripheral region of the touch panel 200, And connected to the seventh sensing pad RX7 through an external wiring formed in the peripheral region.

As described above, according to this embodiment, each of the sensing blocks extending in the column direction and arranged in the row direction is connected to the right-driving line, the left-driving line and the right- Wherein one driving electrode orthogonal to the sensing line covers two sensing electrodes, and each of the two sensing electrodes is electrically separated from the sensing line.

Accordingly, since two sensing electrodes correspond to one driving electrode, the number of connection wirings required to connect the driving electrodes can be reduced and the number of driving pads can be reduced.

In addition, since the plurality of sensing electrodes correspond to one driving electrode, the time required for scanning the entire touch panel can be reduced.

In addition, since the driving lines are disposed on both sides of the sensing line, the boundary condition of the touch panel can be uniformly maintained as compared with the touch panel having the driving line disposed on only one side of the sensing line. Therefore, the sensing efficiency of the touch panel can also be improved.

Further, since two or more left-sensing electrodes electrically separated from each other are disposed between the left-driving electrodes of the adjacent left-driving lines and the right-driving electrodes of the right-driving lines, Compared to a touch panel in which electrodes are disposed. Accordingly, as the number of wirings increases, the dead zone operating in the touch-sensitive area can be reduced, and the effective touch area can be increased. In addition, since the number of connection wirings is reduced, the number of pads of the touch recognition chip can be reduced.

5 is a plan view for explaining a touch panel according to another embodiment of the present invention.

5, a touch panel 300 according to another embodiment of the present invention includes a first sensing block SB1, a second sensing block SB2, a third sensing block SB3, and a fourth sensing block SB4). In this embodiment, for convenience of explanation, a touch panel having four sensing blocks disposed therein is shown.

Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 extends in the column direction (or the Y axis direction) Or X-axis direction). Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 has a strip shape.

The first sensing block SB1 includes a right-driving line 310, a left-driving line 320, a sensing line 330, a plurality of right-driving connection lines 340, (350) and a plurality of sensing connection wires (360). Driving connection lines 340, the left-driving connection lines 350, and the sensing connection 330. The right-driving line 310, the left-driving line 320, the sensing line 330, Wirings 360 are formed in the same layer. The region between the right-driving line 310 and the sensing line 330 has a zigzag shape. The region between the left-driving line 320 and the sensing line 330 has a zigzag shape.

The right-driving line 310 includes a plurality of right-driving electrodes 312 arranged in the column direction, and is disposed in the right area of the first sensing block SB1. In this embodiment, the number of the right-driving electrodes 312 is five. In this embodiment, the size of each of the right-driving electrodes 312 is equal to each other. Each of the right-driving electrodes 312 has a W-shape corresponding to a region adjacent to the sensing line 330.

The left-driving line 320 includes a plurality of left-driving electrodes 322 arranged in the column direction, and is disposed in the left area of the first sensing block SB1. In this embodiment, the number of the left-driving electrodes 322 is five. In this embodiment, the size of each of the left-driving electrodes 322 is equal to each other. Each of the left-driving electrodes 322 has a W-shape corresponding to a region adjacent to the sensing line 330.

The sensing line 330 includes a plurality of sensing electrodes arranged in a column direction, and is disposed between the right-driving line 310 and the left-driving line 320.

In this embodiment, the sensing line 330 includes a plurality of first sensing electrodes 332 for sensing first sensing signals, a plurality of second sensing electrodes 334 for sensing second sensing signals, And a plurality of third sensing electrodes 336 sensing one sensing signals. Here, one first sensing electrode 332, one second sensing electrode 334, and one third sensing electrode 336 correspond to one right-driving electrode. The sensing line 330 may include first connection lines 337 for cascade-connecting the first sensing electrodes 332, second connection lines 337 for connecting the second sensing electrodes 334 in a cascade manner, And third connection wirings 339 connecting the connection wirings 338 and the third sensing electrodes 336 in a cascade manner.

When viewed on a plane, each of the first sensing electrodes 332 has a rhombic shape, and each of the second sensing electrodes 334 and the third sensing electrodes 336 has a triangular shape. The first connection wiring 337 has an I-shape so as to connect the first sensing electrodes 332 in a cascade manner, and the second connection wiring 338 has two I / And the third connection wiring 339 has a V-shape surrounding the two sides of the first sensing electrode 332. The V- Accordingly, the second sensing electrodes 334 and the third sensing electrodes 336 are symmetrical with respect to the first connection lines 337. The right-driving electrodes 312 of the right-driving line 310 and the left driving electrodes 312 of the left-driving line 320 are connected to the first connection lines 337, Symmetrically.

In this embodiment, each of the right-driving electrodes 312 has a triangular tooth shape, and each of the first and second sensing electrodes 332 and 334 has a triangular tooth shape. Accordingly, the right-driving electrodes 312 and the first and second sensing electrodes 332 and 334 are arranged in a coupling manner.

In this embodiment, each of the left-driving electrodes 322 has a triangular tooth shape, and each of the second and third sensing electrodes 334 and 336 has a triangular tooth shape. Accordingly, the left-driving electrodes 322 and the second and third sensing electrodes 334 and 336 are arranged in a coupling shape.

In this embodiment, the driving electrodes disposed on the same row line among the driving electrodes 312 arranged in the first through fourth sensing blocks SB1, SB2, SB3 and SB4 receive the same driving voltage.

The right-driving connection lines 340 are connected to the right-driving electrodes 312, respectively. In one example, the line widths of each of the right-drive interconnections 340 may be equal to each other. In another example, the line width of each of the right-drive interconnections 340 may gradually increase from the observer's point toward the bottom. In another example, the line width of each of the right-drive interconnections 340 may increase stepwise from the observer's point toward the bottom.

The left-driving connection lines 350 are connected to the left-driving electrodes 322, respectively. In one example, the linewidths of the left-driving connecting lines 350 may be equal to each other. In another example, the line width of each of the left-driving connecting lines 350 may gradually increase from the observer's point toward the bottom. In another example, the line width of each of the left-driving connection wirings 350 may increase stepwise from the observer's point toward the bottom.

The sensing connection wiring 360 includes a first sensing connection wiring connecting the first sensing electrode and one sensing pad and a second sensing connection wiring connecting the second sensing electrode and the other sensing pad.

In this embodiment, the first sensing electrode of the first sensing block SB1 is connected to the second sensing pad RX1 through the external wiring formed in the peripheral region of the touch panel 300, And is connected to the first sensing pad RX1 through an external wiring formed in a peripheral region of the panel 300. [ The first sensing electrode of the second sensing block SB2 is connected to the fourth sensing pad RX4 through the external wiring formed in the peripheral region of the touch panel 300 and the second sensing electrode is connected to the periphery of the touch panel 300 And is connected to the third sensing pad RX3 through the external wiring formed in the region. The first sensing electrode of the third sensing block SB3 is connected to the sixth sensing pad RX6 through an external wiring formed in a peripheral region of the touch panel 300, And is connected to the fifth sensing pad RX5 through an external wiring formed in the peripheral region. The first sensing electrode of the fourth sensing block SB4 is connected to the eighth sensing pad RX8 through an external wiring formed in a peripheral region of the touch panel 300, And connected to the seventh sensing pad RX7 through an external wiring formed in the peripheral region.

As described above, according to this embodiment, each of the sensing blocks extending in the column direction and arranged in the row direction is connected to the right-driving line, the left-driving line and the right- Wherein one driving electrode orthogonal to the sensing line covers two sensing electrodes, and each of the two sensing electrodes is electrically separated from the sensing line.

Accordingly, since two sensing electrodes correspond to one driving electrode, the number of connection wirings required to connect the driving electrodes can be reduced and the number of driving pads can be reduced.

In addition, since the plurality of sensing electrodes correspond to one driving electrode, the time required for scanning the entire touch panel can be reduced.

In addition, since the driving lines are disposed on both sides of the sensing line, the boundary condition of the touch panel can be uniformly maintained as compared with the touch panel having the driving line disposed on only one side of the sensing line. Therefore, the sensing efficiency of the touch panel can also be improved.

Further, since two or more left-sensing electrodes electrically separated from each other are disposed between the left-driving electrodes of the adjacent left-driving lines and the right-driving electrodes of the right-driving lines, Compared to a touch panel in which electrodes are disposed. Accordingly, as the number of wirings increases, the dead zone operating in the touch-sensitive area can be reduced, and the effective touch area can be increased. In addition, since the number of connection wirings is reduced, the number of pads of the touch recognition chip can be reduced.

6 is a plan view illustrating a touch panel according to still another embodiment of the present invention. FIG. 7 is a table for explaining how the sensing signals detected in the touch panel shown in FIG. 6 are mapped to a memory.

6 and 7, the touch panel 400 according to still another embodiment of the present invention includes a first sensing block SB1, a second sensing block SB2, a third sensing block SB3, And a sensing block SB4. In this embodiment, for convenience of explanation, a touch panel having four sensing blocks disposed therein is shown.

Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 extends in the column direction (or the Y axis direction) (Or X-axis direction). Each of the first sensing block SB1, the second sensing block SB2, the third sensing block SB3 and the fourth sensing block SB4 has a strip shape.

The first sensing block SB1 includes a right driving line 410, a sensing line 420, a plurality of right driving connection lines 430, and a plurality of sensing connection lines 440. The right-driving line 410, the sensing line 420, the right-driving connection lines 430, and the sensing connection lines 440 are formed in the same layer. The region between the right-driving line 410 and the sensing line 420 has a zigzag shape.

The right-driving line 410 includes a plurality of right-driving electrodes 412 arranged in the column direction, and is disposed in the right area of the first sensing block SB1. In this embodiment, the number of the right-driving electrodes 412 is five. In this embodiment, the size of each of the right-driving electrodes 412 is equal to each other. Each of the right-driving electrodes 412 has a W-shape corresponding to a region adjacent to the sensing line 420.

The sensing line 420 includes a plurality of sensing electrodes arranged in the column direction and is disposed in the left region of the first sensing block SB1 adjacent to the right driving line 410. [ In this embodiment, the number of the sensing electrodes is ten.

In the present embodiment, the sensing line 420 includes a plurality of first sensing electrodes 422 for sensing first sensing signals, a plurality of second sensing electrodes 424 for sensing second sensing signals, First connection lines 426 connecting the first sensing electrodes 422 connected to each other and second connection lines 428 connecting the second sensing electrodes 424 adjacent to each other. When viewed on a plane, each of the first sensing electrodes 422 and the second sensing electrodes 424 has a triangular shape. The first connection wiring 426 has a shape that surrounds two hypotenuses of the second sensing electrode 424 and the second connection wiring 428 has a shape that surrounds the base of the first sensing electrode 422 Shape. In this embodiment, the first sensing electrode 422 is disposed adjacent to the upper area of the odd-numbered right-driving electrode 412 and the second sensing electrode 422 is disposed adjacent to the lower area of the odd- (424). The second sensing electrode 424 is disposed adjacent to the upper region of the even-numbered right-driving electrode 412 and the first sensing electrode 422 is disposed adjacent to the lower region of the even- do. Accordingly, two sensing electrodes connected to the same sensing pad corresponding to the adjacent right-driving electrodes 412 are arranged.

In this embodiment, two V-shaped grooves are formed on the left side of each of the right-driving electrodes 412, and each of the first and second sensing electrodes 422 and 424 is formed into a triangle shape do. Accordingly, the right-driving electrodes 412 and the first and second sensing electrodes 422 and 424 are arranged in a triangle-like coupling shape.

Driving electrodes arranged on the same row line among the right-driving electrodes 412 arranged in the first through fourth sensing blocks SB1, SB2, SB3 and SB4 are driven by the same right- And receives a voltage.

In this embodiment, two sensing electrodes are disposed adjacent to one driving electrode, but three or more sensing electrodes may be disposed adjacent to one driving electrode.

The right-driving connection lines 430 are connected to the right-driving electrodes 412, respectively. In one example, the linewidths of each of the right-drive interconnections 430 may be equal to each other. In another example, the line width of each of the right-drive interconnections 430 may gradually increase from the observer's point toward the bottom. In another example, the line width of each of the right-drive interconnections 430 may increase stepwise from the observer's point toward the bottom.

The sensing connection wirings 440 include a first sensing connection wiring connecting the first sensing electrode and one sensing pad and a second sensing connection wiring connecting the second sensing electrode and the other sensing pad. In the present embodiment, the first sensing electrode of the first sensing block SB1 is connected to the second sensing pad RX1 through an external wiring formed in the peripheral region of the touch panel 400, And is connected to the first sensing pad RX1 through an external wiring formed in the peripheral region of the panel 400. [ The first sensing electrode of the second sensing block SB2 is connected to the fourth sensing pad RX4 through the external wiring formed in the peripheral region of the touch panel 400 and the second sensing electrode is connected to the periphery of the touch panel 400 And is connected to the third sensing pad RX3 through the external wiring formed in the region. The first sensing electrode of the third sensing block SB3 is connected to the sixth sensing pad RX6 through an external wiring formed in a peripheral region of the touch panel 400, And is connected to the fifth sensing pad RX5 through an external wiring formed in the peripheral region. The first sensing electrode of the fourth sensing block SB4 is connected to the eighth sensing pad RX8 through an external wiring formed in a peripheral region of the touch panel 400, And connected to the seventh sensing pad RX7 through an external wiring formed in the peripheral region.

FIG. 7 is a table for explaining how the sensing signals detected in the touch panel shown in FIG. 6 are mapped to a memory.

7, when the first driving signal is simultaneously applied to the first right-driving electrodes included in the first through fourth sensing blocks SB1, SB2, SB3, and SB4, the first driving signal is applied Each of the first sensing electrode 422 and the second sensing electrode 424 adjacent to the first right-driving electrode detects the induced voltage and stores the detected voltage in the memory through the sensing pads.

For example, when the first sensing electrode 422 is included in the first sensing block SB1, the voltage detected by the first sensing electrode 422 is supplied to the memory through the second sensing pad RX2. . When the second sensing electrode 424 is included in the first sensing block SB1, the voltage detected by the second sensing electrode 424 is stored in the memory through the first sensing pad RX1.

When the first sensing electrode 422 is included in the second sensing block SB2, the voltage detected by the first sensing electrode 422 is stored in the memory through the fourth sensing pad RX4. When the second sensing electrode 424 is included in the second sensing block SB2, the voltage detected by the second sensing electrode 424 is stored in the memory through the third sensing pad RX3.

When the first sensing electrode 422 is included in the third sensing block SB3, the voltage detected by the first sensing electrode 422 is stored in the memory through the sixth sensing pad RX6. When the second sensing electrode 424 is included in the third sensing block SB3, the voltage detected by the second sensing electrode 424 is stored in the memory through the fifth sensing pad RX5.

When the first sensing electrode 422 is included in the fourth sensing block SB4, the voltage detected by the first sensing electrode 422 is stored in the memory through the eighth sensing pad RX8. When the second sensing electrode 424 is included in the fourth sensing block SB41, the voltage detected by the second sensing electrode 424 is stored in the memory through the seventh sensing pad RX7.

Subsequently, when the second driving signal is simultaneously applied to the second right-driving electrode included in each of the first through fourth sensing blocks SB1, SB2, SB3, and SB4, the first right- Each of the first sensing electrode 422 and the second sensing electrode 424 adjacent to the electrode detects the induced voltage and stores the detected voltage in the memory through the sensing pads. A series of operations in which the voltages induced in the first sensing electrode 422 and the second sensing electrode 424 are stored in the memory corresponding to the second right-driving electrode is performed in correspondence with the first right- 1 sensing electrode 422 and the second sensing electrode 424 are stored in the memory, a detailed description thereof will be omitted.

When the second driving signal is simultaneously applied to the third right-driving electrode included in each of the first through fourth sensing blocks SB1, SB2, SB3, and SB4, the first right- Each of the first sensing electrode 422 and the second sensing electrode 424 adjacent to the electrode detects the induced voltage and stores the detected voltage in the memory through the sensing pads. A series of operations in which the voltages induced in the first sensing electrode 422 and the second sensing electrode 424 are stored in the memory corresponding to the third right-driving electrode are performed in correspondence with the first right- 1 sensing electrode 422 and the second sensing electrode 424 are stored in the memory, a detailed description thereof will be omitted.

Subsequently, when the second driving signal is simultaneously applied to the fourth right-driving electrode included in each of the first through fourth sensing blocks SB1, SB2, SB3, and SB4, the first right- Each of the first sensing electrode 422 and the second sensing electrode 424 adjacent to the electrode detects the induced voltage and stores the detected voltage in the memory through the sensing pads. A series of operations in which the voltages induced in the first sensing electrode 422 and the second sensing electrode 424 are stored in the memory corresponding to the fourth right-driving electrode are performed in correspondence with the first right- 1 sensing electrode 422 and the second sensing electrode 424 are stored in the memory, a detailed description thereof will be omitted.

When the second driving signal is simultaneously applied to the fifth right-driving electrode included in each of the first through fourth sensing blocks SB1, SB2, SB3, and SB4, the first right- Each of the first sensing electrode 422 and the second sensing electrode 424 adjacent to the driving electrode detects the induced voltage and stores the detected voltage in the memory through the sensing pads. A series of operations in which voltages induced in the first sensing electrode 422 and the second sensing electrode 424 are stored in the memory corresponding to the fifth right-driving electrode correspond to the first right-driving electrode Since the voltages applied to the first sensing electrode 422 and the second sensing electrode 424 are stored in the memory, a detailed description thereof will be omitted.

When the detected voltage is stored in the memory in accordance with the above-described method, it is possible to check which voltage is low based on the stored voltages, and the position can be recognized as the touch coordinates.

As described above, according to the present embodiment, each of the sensing blocks extending in the column direction and arranged in the row direction includes a right-driving line and a sensing line arranged in parallel to the right-driving line , One right-driving electrode orthogonal to the sensing line covers two sensing electrodes, and each of the two sensing electrodes is electrically separated.

Accordingly, since two sensing electrodes correspond to one right-driving electrode, the number of connection wirings necessary for connecting the right-driving electrode can be reduced and the number of driving pads can be reduced.

In addition, since the plurality of sensing electrodes correspond to one right-driving electrode, the time required for scanning the entire touch panel can be reduced.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. You will understand.

As described above, according to the present invention, since two sensing electrodes correspond to one driving electrode in the structure in which the driving line is disposed on one side of the sensing line, the number of connection wirings necessary for connecting the driving electrodes can be reduced. In addition, since the plurality of sensing electrodes correspond to one driving electrode, the time required for scanning the entire touch panel can be reduced.

In addition, two or more left-sensing electrodes electrically isolated between the left-driving electrode of the left-driving line and the right-driving electrode of the right-driving line adjacent to each other in the structure in which the driving lines are arranged on both sides of the sensing line It is possible to reduce the number of connection terminals compared to a touch panel having one sensing electrode corresponding to one driving electrode. Accordingly, as the number of wirings increases, the dead zone operating in the touch-sensitive area can be reduced, and the effective touch area can be increased. In addition, since the number of connection wirings is reduced, the number of pads of the touch recognition chip can be reduced.

100, 200, 300, 400: touch panel SB1: first sensing block
SB2: second sensing block SB3: third sensing block
SB4: fourth sensing block 120, 230, 330, 420: sensing line
130, 240: Right-drive connection wiring lines 140, 260: Sensing connection wiring lines
122: first sensing electrodes 124: second sensing electrodes
126: first connection wiring 128: second connection wiring
220, 320, 420: left-driving line 250, 350: left-driving connecting line
110, 210, 312, 412: right-drive line
112, 212, 312, 412: Right-driving electrodes
TX1, TX2, ..., TX5: driving pads
RX1, RX2, ..., RX7, RX8: sensing pads

Claims (11)

And a plurality of sensing blocks extending in a column direction and arranged in a row direction,
A right-driving line including a plurality of right-driving electrodes arranged in the column direction;
And a sensing line arranged in the column direction and including a plurality of sensing electrodes arranged in parallel with the right-driving electrodes,
Wherein each of the right-driving electrodes is orthogonally projected to two or more sensing electrodes. The touch panel of claim 1, wherein the right-driving electrodes and the sensing electrodes are formed on the same layer. The touch panel of claim 1, wherein each sensing electrode of the same right-driving electrode is connected to a different sensing pad. The touch panel of claim 1, wherein each of the two sensing electrodes is electrically separated. The touch panel of claim 1, wherein each of the right-driving electrodes and each of the sensing electrodes has a triangular tooth shape, and the right-driving electrodes and the sensing electrodes are arranged in a meshed manner. The touch panel of claim 1, wherein each of the sensing electrodes has a triangular shape, and each of the right-driving electrodes has a triangular shape connected thereto. The touch panel of claim 1, wherein each of the sensing blocks has a strip shape. The touch panel of claim 1, wherein a region between the driving line and the sensing line has a zigzag shape. The touch panel of claim 1, wherein the right-driving electrodes disposed in the same row line among the right-driving electrodes arranged in the sensing blocks receive the same driving voltage. The touch panel of claim 1, wherein each of the sensing blocks further comprises a left-driving line including a plurality of left-driving electrodes. 11. The touch panel of claim 10, wherein the left-driving electrodes, the right-driving electrodes, and the sensing electrodes are formed on the same layer.

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