KR101582887B1 - Touch panel and touch sensing device having the same - Google Patents

Abstract

The touch panel includes a left receiving electrode, a right receiving electrode, left transmitting electrodes, right transmitting electrodes, and a central transmitting electrode. The left receiving electrode includes a first body wiring and first branch portions. The right receiving electrode includes second body wirings and second branch portions parallel to the first body wirings. The left transmission electrodes are arranged in a shape surrounding the first body wiring and the first branch portions. The right transmission electrodes are arranged in a shape surrounding the second body wiring and the second branch portions, and are staggered with each of the left transmission electrodes. The central transmission electrode is disposed between the first body wiring and the second body wiring. Thus, since the electrode patterns and the routing wirings are disposed on the same layer, a separate bridge process for connecting the electrode patterns or the routing wirings is unnecessary, and an insulating film for insulation between the electrode patterns disposed in different layers or the routing wirings is unnecessary The manufacturing cost of the touch panel can be reduced. Further, since the left transmission electrodes and the right transmission electrodes are arranged in a zigzag shape with respect to the reception electrode, multi-point recognition is possible.

Description

TECHNICAL FIELD [0001] The present invention relates to a touch panel and a touch sensing device having the touch panel.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a touch panel and a touch sensing device having the touch panel, and more particularly, to a touch panel capable of reducing manufacturing cost and capable of multi-point recognition and a touch sensing device having the touch panel.

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 sense electrode traces (e.g., traces extending in the X axis direction) (e.g., Y-axis direction traces), and the drive and sense electrode traces are separated by a dielectric material such as PET, glass, or the like.

However, the touch panel, which includes the drive and sense 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.

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)

Accordingly, it is an object of the present invention to provide a touch panel capable of reducing manufacturing cost and capable of multi-point recognition.

Another object of the present invention is to provide a touch sensing device having the above-described touch panel.

In order to achieve the object of the present invention, the touch panel according to an embodiment includes a left receiving electrode, a right receiving electrode, a left transmitting electrode, a right transmitting electrode, and a center transmitting electrode. The left receiving electrode includes a first body wiring and a plurality of first branch portions branched from the first body wiring. The right receiving electrode includes a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring. The left transmission electrode includes a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions. The right transmission electrode includes a plurality of right transmission patterns arranged in a staggered manner to surround the second body wiring and the second branch portions and staggered with each of the left transmission patterns. And the central transmission electrode is disposed between the first body wiring and the second body wiring.

In one embodiment, the left receiving electrode may further include a plurality of first leaf portions branched from each of the first branch portions. Here, the first branch portion and the first leaf portion may form a cross shape.

In one embodiment, the right receiving electrode may further include a plurality of second leaf portions branched from each of the second branch portions. Here, the first branch portion and the second leaf portion may form a cross shape.

In one embodiment, the first branch portion and the second branch portion may be branched in different directions.

In one embodiment, the first branch portion and the second branch portion may be arranged on the same line.

In one embodiment, the first branch portion and the second branch portion may be disposed in a staggered manner.

In one embodiment, the first body wiring and the first branch portion may be orthogonal, and the second body wiring and the second branch portion may be orthogonal.

In one embodiment, the first branch portion branches off from the first body wiring in a counterclockwise direction when viewed on a plane to form an acute angle, and the second branch portion branches clockwise in the second body wiring to form an acute angle .

In one embodiment, each of the first and second body wirings extends in a zigzag shape, the first branch portion branches at an inflection portion of the first body wiring, and the second branch portion is connected to the second body wiring It can be branched at the inflection point.

In one embodiment, the first branch portion may be branched in a V-shape in the first body wiring, and the second branch portion may be branched in a V-shape in the second body wiring.

In one embodiment, each of the first and second body wirings extends in a wavy shape, and the first branch portion is formed at the middle portion between the top portion and the bottom portion of the wavy shape, The second branch portion may be branched toward the right transmission electrode at an intermediate portion between the wavy top portion and the bottom portion.

According to another aspect of the present invention, there is provided a touch sensing apparatus including a touch panel and a circuit board. The touch panel includes a touch sensing area and a peripheral area surrounding the touch sensing area, and a plurality of touch sensing units are formed in the touch sensing area. The circuit board is disposed at one end of the touch sensing area, and senses capacitance in the touch sensing units. Each of the touch sensing units includes a left receiving electrode, a right receiving electrode, a left transmitting electrode, a right transmitting electrode, and a central transmitting electrode. The left receiving electrode includes a first body wiring and a plurality of first branch portions branched from the first body wiring. The right receiving electrode includes a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring. The left transmission electrode includes a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions. The right transmission electrode includes a plurality of right transmission patterns arranged in a staggered manner to surround the second body wiring and the second branch portions and staggered with each of the left transmission patterns. And the central transmission electrode is disposed between the first body wiring and the second body wiring.

In one embodiment, the central transmission electrodes of each of the touch sensing units may be commonly connected to each other.

In one embodiment, the circuit board is electrically connected to the left receiving electrodes, the right receiving electrodes, the left transmitting electrodes, the right transmitting electrodes, and the central transmitting electrode, Circuit. In this case, the capacitance sensing circuit includes a current mirror-based charge integrator circuit. The sensing circuit operates in a self-capacitance mode at the beginning of a touch operation and senses a touch. When a touch is sensed, the electrostatic capacitance sensing circuit operates in a mutual capacitance- Sensing circuit.

In one embodiment, the capacitive sensing circuit may apply a wake-up signal to the central transmitting electrode during a wake-up interval of the touch sensing device.

In one embodiment, the capacitive sensing circuit may apply a ground voltage to the central transmission electrode during a touch sensing period of the touch sensing device. Here, when a ground voltage is applied to the central transmission electrode, the left reception electrode may receive a voltage induced in the left transmission patterns, and the right reception electrode may receive a voltage induced in the right transmission patterns .

In one embodiment, the capacitive sensing circuitry may control the central transmitting electrode to remain electrically floating during a touch sensing interval of the touch sensing device. Here, when the central transmission electrode electrically floats, the left receiving electrode may receive a voltage induced in the left transmission patterns and a voltage induced in the right transmission patterns, and the right reception electrode may receive a voltage induced in the right transmission The voltage induced in the patterns and the voltage induced in the left transmission patterns.

In one embodiment, the capacitance sensing circuit includes a transmission circuit portion connected to each of the transmission electrodes, for applying a square wave transmission signal to the transmission electrode, and a transmission circuit portion connected to each of the reception electrodes, And a reception circuit for receiving the square wave reception signal. The receiving circuit includes a receiving switch for connecting any one of the receiving electrodes and the charge integrator circuit to each other to provide a received signal transmitted through the receiving electrode to the charge integrator circuit, And a receiving electrode coupler coupled to the signal line and outputting a summed voltage flowing through the coupled signal line.

According to the touch panel and the touch sensing device having the touch panel, since the electrodes and the routing lines are disposed on the same layer, a separate bridge process for connecting various electrodes or routing lines or an insulating film is unnecessary, have. In addition, since the left transmission patterns and the right transmission patterns are arranged in a zigzag shape on the basis of the left reception electrode and the right reception electrode, multi-point recognition is possible. In addition, a wake-up signal is provided to the central transmission electrode disposed between the left reception electrode and the right reception electrode during the wake-up period, and the ground voltage is applied during the touch sensing period to prevent the adverse influence due to the noise signal of the display panel . In addition, a wake-up signal is provided to the central transmission electrode during a wake-up period, and electrically floating during the touch sensing period enables a fine touch operation to be generated on the touch panel to be recognized.

1 is an exploded perspective view of a touch sensing device employing a touch panel according to the present invention.
2 is a plan view schematically illustrating a touch panel according to an embodiment of the present invention.
FIG. 3A is an enlarged view showing regions A and B of FIG. 2, respectively.
FIG. 3B is a cross-sectional view taken along the line I-I 'of FIG. 3A.
FIG. 4 is a plan view schematically illustrating the touch sensing unit shown in FIG. 2. FIG.
5 is a plan view for explaining a touch sensing unit according to another embodiment of the present invention.
6 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
7 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
8 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
9 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
10 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
11 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
12 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
13 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.
14 is a schematic view for explaining a touch sensing apparatus according to an embodiment of the present invention.
15 is a schematic view for explaining the circuit board shown in Fig.
FIG. 16 is an equivalent circuit diagram schematically illustrating an example of the electrostatic capacitance sensing circuit for a touch panel of the mutual-capacitance type shown in FIG.
17 is a waveform diagram for explaining the operation of the capacitance sensing circuit shown in Fig.
18 is a schematic view for explaining a touch sensing apparatus according to another embodiment of the present invention.

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.

1 is an exploded perspective view of a touch sensing device employing a touch panel according to the present invention.

1, the touch sensing apparatus includes a touch panel 10, a circuit board 20, and a transparent window 30, and is disposed on the display panel 40.

The touch panel 10 may be formed of a rigid material such as reinforced glass or acrylic resin or a rigid PET (Polyethylene Terephthalate), PC (Polycarbonate), PES (Polyethersulfone), PI (Polyimide), PMMA (PolyMethly MethaAcrylate ), And the like.

The touch panel 10 includes a touch sensing area TA and a peripheral area PA and may be electrically connected to the circuit board 20 through a wiring connection member WCM.

The touch sensing area TA is an area for sensing input information generated by a user's screen touch or gesture, and may include a plurality of touch sensing units. Each of the touch sensing units includes a left receiving electrode, a right receiving electrode, a left transmitting electrode disposed in a left region of the receiving electrode, a right transmitting electrode disposed in a right region of the receiving electrode, And a central transmitting electrode disposed between the electrodes. A detailed description of the above-described touch sensing unit will be described later.

In the following description, it is assumed that the transmission electrode receives a square wave transmission signal for touch sensing, and the reception electrode receives the induced signal of the transmission signal. However, the receiving electrode may receive a square wave transmitting signal for touch sensing, and the transmitting electrode may receive the induced signal of the transmitting signal.

The transparent window 30 has a contact sensing area 34 and an outer area 35 and is exposed to the outside to receive a contact of a conductive object such as a user's body or a stylus pen. Therefore, the transparent window 30 should have a high hardness. The transparent window 30 is made of a hardened plastic or a combination of PMMA, PC, and PET, and has a thickness of 0.5 T or more.

When the touch sensing units are formed on the upper surface of the touch panel 10, the transparent window 30 may be disposed on the touch panel 10. Meanwhile, when the touch sensing units are formed on the back surface of the touch panel 10, the transparent window 30 may be omitted.

In addition, the touch sensing units may be formed on the uppermost glass of the display panel 40. For example, when the touch sensing units are formed on the top surface of the uppermost glass of the display panel 40, the transparent window 30 may be disposed on the display panel 40. As another example, when the touch sensing units are formed on the back surface of the uppermost glass of the display panel 40, the transparent window 30 may be omitted.

The peripheral area PA surrounds the touch sensing area TA and has a wiring pattern for transmitting a sensing signal generated in the touch sensing area TA. The touch sensing area TA and the peripheral area PA may be integrated or may be integrated in the peripheral area PA with the input information of the user .

2 is a plan view schematically illustrating a touch panel according to an embodiment of the present invention. FIG. 3A is an enlarged view showing regions A and B of FIG. 2, respectively. FIG. 3B is a cross-sectional view taken along the line I-I 'of FIG. 3A. 4 is a plan view schematically illustrating the touch sensing unit 1100 shown in FIG. 3A, the area A is an area extracted from a part of the touch sensing unit 1100 adjacent to the pad part, and the area B is an area excerpted from a part of the touch sensing unit 1100 adjacent to the button part.

Referring to FIGS. 2, 3A, 3B, and 4, the touch panel includes a transparent substrate and a plurality of touch sensing units 1100 formed on the transparent substrate. In this embodiment, the touch sensing units 1100 extend in the first direction D1 and are arranged in the second direction D2. The first direction D1 and the second direction D2 may be perpendicular to each other. In this embodiment, an example in which 11 touch sensing units are arranged is shown.

Each of the touch sensing units 1100 includes a left receiving electrode 1110, a right receiving electrode 2110, a left transmitting electrode 1120 disposed in the left region of the left receiving electrode 1110, a right receiving electrode 1110 A left routing wiring 1140 connected to the left transmission electrode 1120, a right routing wiring 1150 connected to the right transmission electrode 1130 and a right routing electrode 1130 connected to the right transmission electrode 1130. The right transmission electrode 1130, And a center transmitting electrode 1160 disposed between the right receiving electrode 1110 and the right receiving electrode 2110. The left receiving electrode 1110, the right receiving electrode 2110, the left transmitting electrode 1120, the right transmitting electrode 1130, the left routing wiring 1140, the right routing wiring 1150, The transmitting electrode 1160 is formed on the same layer.

The left receiving electrode 1110 includes a first body wiring 1112 extending in the first direction D1 and a plurality of first branch portions 1132 branched from the first body wiring 1112 along the second direction D2. Gt; 1114 < / RTI > For example, the width of the first body wiring 1112 and the width of the first branch portion 1114 may be the same. As another example, the width of the first body wiring 1112 may be greater than the width of the first branch portion 1114. In the present embodiment, the first body wiring 1112 has a linear shape, but may have a curved shape. In addition, although the first branch portion 1114 has a linear shape, the first branch portion 1114 may have a curved shape.

The right receiving electrode 2110 includes a second body wiring 2112 extending in the first direction D1 and a plurality of second branches 2112 branched from the second body wiring 2112 along the second direction D2. (2114). For example, the width of the second body wiring 2112 and the width of the second branch 2114 may be the same. As another example, the width of the second body wiring 1112 may be greater than the width of the second branch portion 2114. In the present embodiment, the second body wiring 1112 has a linear shape, but it may have a curved shape. In addition, although the second branch portion 2114 has a linear shape, it may have a curved shape. In this embodiment, the first branch portion 1114 and the second branch portion 2114 are arranged on the same line.

The left transmission electrode 1120 includes a first left transmission pattern 1122, a second left transmission pattern 1124 and a third left transmission pattern 1126, and the first body wiring 1112 and the first And is disposed at a predetermined distance from the branch portions 1114 so as to surround the first body wiring 1112 and the first branch portions 1114 from one side. For convenience of explanation, the left transmission electrode 1120 includes three left transmission patterns, but is not limited thereto. The spacing between the left transmission electrode 1120 and the first body wiring 1112 and the first branch portions 1114 may be uniform.

Specifically, the first left transmission pattern 1122, the second left transmission pattern 1124, and the third left transmission pattern 1126 are formed in a tooth shape so that the first body wiring 1112 and the first Branch portions 1114 are surrounded. Each of the first left transmission pattern 1122 and the third left transmission pattern 1126 includes three tooth members. The width of one tooth member disposed at the center portion is twice the width of each of the tooth members disposed at the outer portion.

The second left transmission pattern 1124 includes five tooth members. The widths of the three tooth members disposed at the center are equal to each other, and the widths of the two tooth members disposed at the outer frame portion are equal to each other. The width of the tooth member disposed at the outer portion is half the width of the tooth member disposed at the center portion.

The right transmission electrode 1130 includes a first right transmission pattern 1132 and a second right transmission pattern 1134 and is connected to the second body wiring 2112 and the second branch portions 2114 And are arranged to surround the second body wiring 2112 and the second branch portions 2114 from the other side. The spacing between the right transmission electrode 1130 and the second body wiring 2112 and the second branch portions 2114 may be uniform. For convenience of explanation, the right transmission electrode 1130 includes two left transmission patterns, but is not limited thereto.

Specifically, the first right transmission pattern 1132 and the second right transmission pattern 1134 are formed in a tooth shape to surround the second body wiring 2112 and the second branch portions 2114.

Each of the first right transmission pattern 1132 and the second right transmission pattern 1134 includes five tooth members. The widths of the three tooth members disposed at the center are equal to each other, and the widths of the two tooth members disposed at the outer frame portion are equal to each other. The width of the tooth member disposed at the outer portion is half the width of the tooth member disposed at the center portion.

4, the left transmission electrode 1120 includes three left transmission patterns, and the right transmission electrode 1130 includes two right transmission patterns. However, the left transmission electrode 1120 may include n (n is a natural number) left transmission patterns and the right transmission electrode 1130 may include (n-1) right transmission patterns. For example, the left transmission electrode 1120 includes ten left transmission patterns, and the shape of the two left transmission patterns corresponding to the outermost portion includes three tooth members as the first left transmission pattern 1122 And the shape of the remaining left transmission patterns may include five teeth like the second left transmission pattern 1124. [

The left routing wiring 1140 includes a first left routing wiring 1142, a second left routing wiring 1144 and a third left routing wiring 1146, And is connected to the left transmission electrode 1120. The left transmission electrode 1120 and the right transmission electrode 1120 are connected to each other. The first left routing wiring 1142 is connected to the first left transmission pattern 1122 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112. The second left routing wiring 1144 is connected to the second left transmission pattern 1124 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112. The third left routing wiring 1146 is connected to the third left transmission pattern 1126 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112.

The right routing wiring 1150 includes the first right routing wiring 1152 and the second right routing wiring 1154 and the right routing wiring 1150 includes the right transmission wiring 1150, And is connected to the right transmission electrode 1130. The first right routing wiring 1152 is connected to the first right transmission pattern 1132 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112. The second right routing wiring 1154 is connected to the second right transmission pattern 1134 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112.

The central transmission electrode 1160 extends in the first direction D1 and is disposed between the first body wiring 1112 of the left receiving electrode 1110 and the second body wiring 2112 of the right receiving electrode 2110 . The central transmission electrodes 1160 provided in each of the touch sensing units 1100 are commonly connected to each other. The central transmission electrode 1160 is provided with a wake-up signal from an external capacitance sensing circuit (not shown) during a wake-up interval. Here, the wake-up interval refers to a section between a sleep interval and a touch sensing interval. Accordingly, in order to activate the touch sensing apparatus, the touch sensing apparatus is activated by applying a wake-up signal to the central transmission electrode 1160, which is commonly connected to each other even if transmission signals are not applied to the left transmission electrodes and the right transmission electrodes The time required can be shortened.

Meanwhile, the central transmission electrode 1160 receives a ground voltage from the capacitance sensing circuit during a touch sensing period. Accordingly, during the touch sensing period, signals that can be transmitted from the display panel disposed at the lower portion of the touch panel formed with the touch sensing units 1100 can be blocked. It is also possible to prevent a transmission signal applied to the left transmission electrode from being induced to the adjacent right reception electrode or a transmission signal applied to the right transmission electrode from being induced to the adjacent left reception electrode.

On the other hand, the central transmission electrode 1160 may maintain an electrically floating state during a touch sensing period. At this time, the transmission signal applied to the left transmission electrode may be induced to the adjacent right reception electrode, and the transmission signal applied to the right transmission electrode may be induced to the adjacent left reception electrode. Accordingly, a fine touch operation that may occur in the touch panel can be recognized.

The ground mode in which the ground voltage is applied and the floating mode in which the electric floating state is maintained may be selected by the designer designing the touch sensing chip or may be designed to be selected by the user of the touch sensing device. For example, the ground mode may be employed when the size of the touch sensing unit 1100 is large, and the floating mode may be employed when the size of the touch sensing unit 1100 is small. Alternatively, the ground mode may be employed when the noise signal of the display panel 40 disposed at the lower portion of the touch panel 10 is large, and the floating mode may be employed when the display panel 40 Can be employed when the noise signal is small.

The touch panel may further include a ground line GNL surrounding the touch sensing area TA formed with the touch sensing units 1100. The ground line GNL includes a main-ground line GNLM, a first sub-ground line GNLS1, and a second sub-ground line GNLS2.

The main-ground wiring GNLM is disposed in a shape surrounding the touch sensing area TA.

The first sub-ground line GNLS1 is connected to the left routing wiring 1142 closest to the routing wiring and the routing wiring connected to the left receiving electrode 1110 in the peripheral area PA. . The first sub-ground line GNLS1 extends to a region where the peripheral area PA is in contact with the touch sensing area TA to define a left ground pattern. Thus, it is possible to prevent a signal transmitted through the left routing wiring 1140 from adversely affecting the left receiving electrode 1110.

The second sub-ground line GNLS2 is connected to the routing wiring connected to the right reception electrode 2110 in the peripheral area PA and the right routing wiring (that is, the first right routing wiring 1152) closest to the routing wiring, . The second sub-ground line GNLS2 extends to a region where the peripheral area PA is in contact with the touch sensing area TA to define a left ground pattern. Accordingly, it is possible to prevent a signal transmitted through the right routing wiring 1150 from adversely affecting the right receiving electrode 2110.

The left routing wires 1140 of the touch sensing unit 1100 extend to the peripheral area PA to define left transmission pad members and the right routing wires 1150 of the touch sensing unit 1100 And extends to the peripheral area PA to define the right transmission pad members. The width of each of the left transmission pads may be greater than the width of each of the left routing pads 1140 and the width of each of the right transmission pads may be greater than the width of each of the right routing pads 1150.

The left receiving electrode 1110 of the touch sensing unit 1100 defines a receiving pad with a reduced width in the peripheral area PA. Since the left receiving electrode 1110 and the left transmitting electrode 1120 are spaced apart from each other by a predetermined distance, a plurality of dummy electrode patterns DMP may be disposed in the spaced space. In addition, since the left receiving electrode 1110 and the right transmitting electrode 1130 are spaced apart by a predetermined distance, a plurality of dummy electrode patterns DMP may be disposed in the spaced apart space.

A plurality of dummy electrode patterns DMP may be disposed between each of the left transmission electrodes 1120 and the left routing wiring 1140 closest to the corresponding left transmission electrode 1120. A plurality of dummy electrode patterns DMP may be disposed between the right transmission electrode 1130 and the right routing wiring 1150 closest to the right transmission electrode 1130.

3B, the left receiving electrode 1110, the left transmitting electrode 1120, the right transmitting electrodes 1130, the left routing wiring 1140, the right routing wiring 1150, The right receiving electrode 2110, the central transmitting electrode 1160, and the dummy electrode pattern DMP are disposed on the same layer. The left transmission electrode 1120, the right transmission electrode 1130, the left routing wiring 1140, the right routing wiring 1150, the right reception electrode 2110 ), The central transmitting electrode 1160 and the dummy electrode patterns DMP include the same material and can be manufactured simultaneously through the same mask.

The left receiving electrode 1110, the left transmitting electrode 1120, the right transmitting electrodes 1130, the left routing wiring 1140, the right routing wiring 1150, the right receiving electrode 2110, Examples of the transparent conductive material applicable to the central transmission electrode 1160 and the dummy electrode patterns DMP include oxides such as indium tin oxide (ITO), indium zinc oxide (IZO), and zinc oxide (ZO) Metal nanowires, conductive polymers, silver nano wires, and graphenes.

The left receiving electrode 1110, the left transmitting electrode 1120, the right transmitting electrodes 1130, the left routing wiring 1140, the right routing wiring 1150, the right receiving electrode 2110, The central transmitting electrode 1160 and the dummy electrode patterns DMP are collectively sputtered on one surface of the touch panel 10 and then etched according to the electrodes and the wiring pattern to be integrally formed on one surface of the touch panel 10 .

4, the widths of the first left transmission pattern 1122, the second left transmission pattern 1124, and the third left transmission pattern 1126 are shown to be equal to each other. However, as the distance from the left transmission pad member increases, May increase. Although the widths of the first right transmission pattern 1132 and the second right transmission pattern 1134 are shown to be equal to each other, the width may gradually increase as the distance from the right transmission pad member increases.

As described above, according to this embodiment, since the electrode patterns or the routing wirings are disposed on the same layer, a separate bridge process for connecting the electrode patterns or the routing wirings is unnecessary, and the electrode patterns arranged in different layers An insulating film for insulation between the routing wirings is unnecessary. Therefore, the manufacturing cost of the touch panel can be reduced.

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

5, the touch sensing unit 3100 includes a left receiving electrode 3110, a right receiving electrode 3210, and a left transmitting electrode 3120 disposed in the left region of the left receiving electrode 3110 A right transmission electrode 3130 disposed on the right side of the right receiving electrode 3210, a left routing wiring 3140 connected to the left transmission electrode 3120, a right routing wiring 3140 connected to the right transmission electrode 3130, And a central transmitting electrode 3160 disposed between the left receiving electrode 3110 and the right receiving electrode 3210. [

The left receiving electrode 3110 includes a first body wiring 3112 extending in a first direction D1 and a plurality of first branch portions 3110b branched from the first body wiring 3112 along a second direction D2. And a plurality of first leaf portions 3116 branched from the first branch portions 3114 and the first branch portions 3114, respectively. The first branch portion 3114 and the first leaf portions 3116 form a cross shape.

The right receiving electrode 3210 includes a second body wiring 3212 extending in the first direction D1 and a plurality of second branches 3212 branched from the second body wiring 3212 along the second direction D2. And a plurality of second leaf portions 3216 branched from the second branch portions 3214 and the second branch portions 3214, respectively. The second branch portion 3214 and the second leaf portions 3216 form a cross shape.

The left transmission electrode 3120 includes a first left transmission pattern 3122, a second left transmission pattern 3124 and a third left transmission pattern 3126 and the first body wiring 3112, The first branch portions 3114 and the first leaf portions 3116 are spaced apart from the first branch portions 3114 and the first leaf portions 3116 by a predetermined distance to surround the first body wirings 3112, . For convenience of explanation, the left transmission electrode 3120 includes three left transmission patterns, but is not limited thereto. The spacing between the left transmission electrode 3120 and the first body wiring 3112 and the first branch portions 3114 may be uniform.

Specifically, the first left transmission pattern 3122, the second left transmission pattern 3124, and the third left transmission pattern 3126 are formed in a tooth shape so that the first body wiring 3112 and the first Branch portions 3114 are surrounded. Each of the first left transmission pattern 3122 and the third left transmission pattern 3126 includes three tooth members. The width of one tooth member disposed at the center portion is twice the width of each of the tooth members disposed at the outer portion.

The second left transmission pattern 3124 includes five tooth members. The widths of the three tooth members disposed at the center are equal to each other, and the widths of the two tooth members disposed at the outer frame portion are equal to each other. The width of the tooth member disposed at the outer portion is half the width of the tooth member disposed at the center portion.

Since the first branch portion 3114 and the first leaf portions 3116 form a cross shape in this embodiment, the first branch portion 3114 and the first leaf portions 3116 surrounding the first branch portion 3114 and the first leaf portions 3116, A cross-shaped opening is formed in the left transmission electrode 3120. 5, a greater number of bent portions are formed than the bent portions formed on the left receiving electrode 1110 shown in FIG. 4, and the left transmitting electrode 3120 shown in FIG. A larger number of bent portions are formed than the trough portions formed in the left transmission electrode 1120 shown in FIG. 4, so that the efficiency of generating the electric field flux formed between the transmission electrode and the reception electrode can be increased.

The right transmission electrode 3130 includes a first right transmission pattern 3132 and a second right transmission pattern 3134 and includes the second body wiring 3212, the second branch portions 3214, The second branch portions 3214, and the second leaf portions 3216 at a predetermined interval from the second leaf portions 3216. The first and second branch portions 3212, The spacing between the right transmission electrode 3130 and the second body wiring 3212, the second branch portions 3214, and the second leaf portions 3216 may be uniform. For convenience of explanation, the right transmission electrode 3130 includes two left transmission patterns, but is not limited thereto.

Specifically, the first right transmission pattern 3132 and the second right transmission pattern 3134 are formed in a tooth shape to surround the first body wiring 3112 and the first branch portions 3114.

Each of the first right transmission pattern 3132 and the second right transmission pattern 3134 includes five tooth members. The widths of the three tooth members disposed at the center are equal to each other, and the widths of the two tooth members disposed at the outer frame portion are equal to each other. The width of the tooth member disposed at the outer portion is half the width of the tooth member disposed at the center portion.

Since the second branch portion 3214 and the second leaf portions 3216 form a cross shape in the present embodiment, the second branch portion 3214 and the second leaf portions 3216 surround the second branch portion 3214 and the second leaf portions 3216, The right transmission electrode 3130 is formed with a cross-shaped opening. 5, a greater number of bent portions are formed than the bent portions formed on the right receiving electrode 1210 shown in FIG. 4, and the right transmitting electrode 3130 shown in FIG. A greater number of bent portions are formed than the trough portions formed in the right transmission electrode 1130 shown in FIG. 4, so that the efficiency of generating the electric field flux formed between the transmission electrode and the reception electrode can be increased.

For convenience of explanation, it has been described that the left transmission electrode 3120 includes three left transmission patterns and the right transmission electrode 3130 includes two right transmission patterns. However, the left transmission electrode 3120 may include n (n is a natural number) left transmission patterns and the right transmission electrode 3130 may include (n-1) right transmission patterns. For example, the left transmission electrode 3120 includes ten left transmission patterns, and the shape of the two left transmission patterns corresponding to the outermost portion includes three tooth members as the first left transmission pattern 3122 And the shape of the remaining left transmission patterns may include five teeth like the second left transmission pattern 3124. [

The left routing wiring 3140 includes a first left routing wiring 3142, a second left routing wiring 3144 and a third left routing wiring 3146. The left routing wiring 3140 includes a first left routing wiring 3142, And is connected to the left transmission electrode 3120 by being disposed in an area opposite to the reception electrode 3110. The first left routing wiring 3142 is connected to the first left transmission pattern 3122 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 3112. [ The second left routing wiring 3144 is connected to the second left transmission pattern 3124 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 3112. The third left routing wiring 3146 is connected to the third left transmission pattern 3126 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 3112. [

The right routing wiring 3150 includes the first right routing wiring 3152 and the second right routing wiring 3154. The right routing wiring 3150 is connected to the right reception wiring 3210 And is connected to the right transmission electrode 3130. [ The first right routing wiring 3152 is connected to the first right transmission pattern 3132 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 3112. [ The second right routing wiring 3154 is connected to the second right transmission pattern 3134 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 3112.

The central transmission electrode 3160 extends in the first direction D1 and is disposed between the first body wiring 3112 of the left receiving electrode 3110 and the second body wiring 3212 of the right receiving electrode 3210 . The central transmission electrodes 3160 provided in each of the touch sensing units 3100 are commonly connected to each other. For example, the central transmission electrode 3160 may receive a wake-up signal from an external capacitance sensing circuit (not shown) during a wake-up period and may receive a ground voltage from the capacitance sensing circuit during a touch sensing period, . As another example, the central transmission electrode 3160 may be provided with a wake-up signal from an external capacitance sensing circuit (not shown) during the wake-up period and may remain electrically floating during the touch sensing period.

As described above, the touch sensing unit shown in FIG. 5 further includes the leaf portions in the branch portions of each of the reception electrodes, as compared with the touch sensing unit shown in FIG. Accordingly, it is possible to increase the efficiency of generating the electric field flux formed between the transmitting electrode and the receiving electrode.

In addition, according to the present embodiment, since the electrode patterns and the routing wirings are disposed on the same layer, a separate bridge process for connecting the electrode patterns or the routing wirings is unnecessary, and the electrode patterns disposed in different layers or the insulation An insulating film is not required. Therefore, the manufacturing cost of the touch panel can be reduced.

6 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

6, the touch sensing unit 1200 includes a left receiving electrode 1210, a right receiving electrode 2210, and a left transmitting electrode 1220 disposed in the left region of the left receiving electrode 1210, A right transmission electrode 1230 disposed on the right side of the right receiving electrode 2210, a left routing wiring 1240 connected to the left transmission electrode 1220, a right routing wiring 1240 connected to the right transmission electrode 1230, And a central transmitting electrode 1260 disposed between the left receiving electrode 1210 and the right receiving electrode 2210. [

The left reception electrode 1210 includes a first body wiring 1212 extending in a first direction D1 and a plurality of first branch portions 1232 branched from the first body wiring 1212 along a second direction D2. (1214). Since the left receiving electrode 1210 is the same as the left receiving electrode 1110 of FIG. 4, detailed description is omitted.

The right reception electrode 2210 includes a second body wiring 2212 extending in the first direction D1 and a plurality of second branches 2232 branched from the second body wiring 2212 along the second direction D2. (1214). Since the right receiving electrode 2210 is the same as the left receiving electrode 2110 of FIG. 4, detailed description is omitted.

The left transmission electrode 1220 includes a first left transmission pattern 1222, a second left transmission pattern 1224 and a third left transmission pattern 1226, and the first body wiring 1212 and the first And is disposed at a predetermined interval from the branch portions 1214 so as to surround the first body wiring 1212 and the first branch portions 1214 from one side. The first left transmission pattern 1222, the second left transmission pattern 1224, and the third left transmission pattern 1226 are the same as the first left transmission pattern 1222 described in FIG. 4 except that one side has a sawtooth shape, The first left transmission pattern 1122, the second left transmission pattern 1124, and the third left transmission pattern 1126, detailed description thereof will be omitted.

The right transmission electrode 1230 includes a first right transmission pattern 1232 and a second right transmission pattern 1234. The right transmission electrode 1230 is connected to the second body wiring 2212 and the second branch portions 2214, And is arranged in a shape to surround the second body wiring 2212 and the second branch portions 2214 from the other side. The first right transmission pattern 1232 and the second right transmission pattern 1234 are the same as those of the first right transmission pattern 1132 and the second right transmission pattern 1134 ), And thus the detailed description thereof will be omitted.

The left routing wiring 1240 includes a first left routing wiring 1242, a second left routing wiring 1244, and a third left routing wiring 1246. Since the left routing wiring 1240 is the same as the left routing wiring 1140 described in FIG. 4, detailed description is omitted. In this embodiment, the left routing wiring 1240 has a linear shape, but it may have a saw-tooth shape.

The right routing wiring 1250 includes a first right routing wiring 1252 and a second right routing wiring 1254. Since the right routing wiring 1250 is the same as the right routing wiring 1150 described in FIG. 4, a detailed description will be omitted. In the present embodiment, the right routing wiring 1250 has a linear shape, but may have a saw-tooth shape.

6, the widths of the first left transmission pattern 1222, the second left transmission pattern 1224, and the third left transmission pattern 1226 are equal to each other. However, as the distance from the left transmission pad member increases The width may gradually increase. In addition, although the widths of the first right transmission pattern 1232 and the second right transmission pattern 1234 are shown to be equal to each other, the width may gradually increase as the distance from the right transmission pad member increases.

The central transmission electrode 1260 is the same as the central transmission electrode 1160 illustrated in FIG. 4, and thus a detailed description thereof will be omitted.

Although not shown in FIG. 6, first leaf portions may be further formed in each of the first branch portions 1214 to form a cross shape, as illustrated in FIG. Cross-shaped openings may be formed in the first left transmission pattern 1222, the second left transmission pattern 1224, and the third left transmission pattern 1226 of the left transmission electrode 1220. Accordingly, efficiency of generating the electric field flux formed between the left transmitting electrode 1220 and the left receiving electrode 1210 can be increased.

In addition, second leaf portions may be further formed in each of the second branch portions 2214 to form a cross shape. A cross-shaped opening may be formed in the first right transmission pattern 1232 and the second right transmission pattern 1234 of the right transmission electrode 1230. Accordingly, the efficiency of generating the electric field flux formed between the right transmitting electrode 1230 and the right receiving electrode 2210 can be increased.

7 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

7, the touch sensing unit 1300 includes a left reception electrode 1310 formed on the same layer, a right reception electrode 2310, a left transmission electrode 1320 disposed in the left region of the left reception electrode 1310, A right transmission electrode 1330 disposed on the right side of the right receiving electrode 2310, a left routing wiring 1340 connected to the left transmission electrode 1320, a right routing wiring 1340 connected to the right transmission electrode 1330, And a central transmitting electrode 1360 disposed between the left receiving electrode 1310 and the right receiving electrode 2310. [

The left receiving electrode 1310 includes a first body wiring 1312 extending in the first direction D1 and a plurality of first branch portions 1312 branched from the first body wiring 1312 along the second direction D2. (1314). The width of the first body wiring 1312 and the width of the first branch portion 1314 may be the same.

The right receiving electrode 2310 includes a second body wiring 2312 extending in the first direction D1 and a plurality of second branches 2312 branched from the second body wiring 2312 in the second direction D2. (2314). The width of the second body wiring 2312 and the width of the second branch portion 2314 may be the same.

In the present embodiment, the first branch wiring 1314 of the left receiving electrode 1310 and the second branch wiring 2314 of the right receiving electrode 2310 are arranged in an inverted shape. In other words, the first branch portion 1314 branches toward the left transmission electrode 1320, and the second branch portion 2314 branches toward the right transmission electrode 1330. Accordingly, the first and second branch portions 1314 and 2314 may be arranged in a staggered manner with respect to the central transmitting electrode 1360. Although the first and second body wirings 1312 and 2312 have a linear shape in FIG. 7, they may have a curved shape.

The left transmission electrode 1320 includes a first left transmission pattern 1322, a second left transmission pattern 1324 and a third left transmission pattern 1326, and the first body wiring 1312 and the first And is disposed at a predetermined distance from the branch portions 1314 so as to surround the first body wiring 1312 and the first branch portions 1314 from one side. The first left transmission pattern 1322, the second left transmission pattern 1324 and the third left transmission pattern 1326 are the same as the first left transmission pattern 1122, Pattern 1124 and the third left transmission pattern 1126, detailed description thereof will be omitted.

The right transmission electrode 1330 includes a first right transmission pattern 1332 and a second right transmission pattern 1334 and is connected to the second body wiring 2312 and the second branch portions 2314 And is arranged in a shape to surround the second body wiring 2312 and the second branch portions 2314 from the other side. Since the first right transmission pattern 1332 and the second right transmission pattern 1334 are similar to the first right transmission pattern 1132 and the second right transmission pattern 1134 described in FIG. 4, It is omitted.

The left routing wiring 1340 includes a first left routing wiring 1342, a second left routing wiring 1344, and a third left routing wiring 1346. Since the left routing wiring 1340 is the same as the left routing wiring 1140 described in FIG. 4, detailed description is omitted. In the present embodiment, the left routing wiring 1340 has a linear shape, but may have a saw-tooth shape.

The right routing wiring 1350 includes a first right routing wiring 1352 and a second right routing wiring 1354. Since the right routing wiring 1350 is the same as the right routing wiring 1150 described with reference to FIG. 4, detailed description is omitted. In the present embodiment, the right routing wiring 1350 has a linear shape, but may have a saw-tooth shape. If the left routing wiring 1340 and the right routing wiring 1350 have a sawtooth shape, it is possible to prevent a moire phenomenon generated in an image of a display panel disposed under the touch panel.

The central transmission electrode 1360 is the same as the central transmission electrode 1160 described in FIG. 4, and thus a detailed description thereof will be omitted.

Although not shown in FIG. 7, first leaf portions may be further formed in each of the first branch portions 1314 to form a cross shape, as illustrated in FIG. Cross-shaped openings may be formed in the first left transmission pattern 1322, the second left transmission pattern 1324, and the third left transmission pattern 1326 of the left transmission electrode 1320. Accordingly, efficiency of generating the electric field flux formed between the left transmission electrode 1320 and the left reception electrode 1310 can be increased.

In addition, second leaf portions may be further formed in each of the second branch portions 2314 to form a cross shape. A cross-shaped opening may be formed in the first right transmission pattern 1332 and the second right transmission pattern 1334 of the right transmission electrode 1330. Accordingly, the efficiency of generating the electric field flux formed between the right transmission electrode 1330 and the right reception electrode 2310 can be increased.

8 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

8, the touch sensing unit 1400 includes a left receiving electrode 1410, a right receiving electrode 2410 formed on the same layer, a left transmitting electrode 1420 disposed in the left region of the left receiving electrode 1410, A right transmission electrode 1430 disposed on the right side of the right reception electrode 2410, a left routing wiring 1440 connected to the left transmission electrode 1420, a right routing wiring 1450 connected to the right transmission electrode 1430, And a central transmitting electrode 1460 disposed between the left receiving electrode 1410 and the right receiving electrode 2410.

The left receiving electrode 1410 includes a first body wiring 1412 extending in a first direction D1 and a plurality of second body wiring 1412 branched from the first body wiring 1412 at a predetermined angle with respect to the second direction D2. 1 branch portions 1414. The width of the first body wiring 1412 and the width of the first branch 1414 may be the same.

The right receiving electrode 2410 includes a second body wiring 2412 extending in a first direction D1 and a plurality of second body wiring 2412 branched from the second body wiring 2412 at a predetermined angle with respect to the second direction D2. 2 branch portions 2414. The width of the second body wiring 2412 and the width of the second branch portion 2414 may be the same. In this embodiment, the first branch portion 1414 and the second branch portion 2412 may be disposed on the same line.

The left transmission electrode 1420 includes a first left transmission pattern 1422, a second left transmission pattern 1424 and a third left transmission pattern 1426, and the first body wiring 1412 and the first And is disposed so as to surround the first body wiring 1412 and the first branch portions 1414 at a predetermined distance from the branch portions 1414. Since the first branch portions 1414 are branched at the obtuse angle or acute angle in the first body wiring 1412 in the present embodiment, the first left transmission pattern 1422, the second left transmission pattern 1424, The groove shape formed in each of the third left transmission patterns 1426 and surrounding the first branch portions 1414 also has a shape inclined from the viewer's point of view. The spacing between the left transmission electrode 1420 and the first body wiring 1412 and the first branch portions 1414 may be uniform.

Specifically, the first left transmission pattern 1422, the second left transmission pattern 1424, and the third left transmission pattern 1426 are formed in an inclined tooth shape, and the first body wiring 1412 and the first branch (1414). Each of the first left transmission pattern 1422 and the third left transmission pattern 1426 includes three inclined tooth members. The width of one tooth member disposed at the center portion is twice the width of each of the tooth members disposed at the outer portion.

The second left transmission pattern 1424 includes five inclined tooth members. The widths of the three inclined tooth members disposed at the center are equal to each other and the widths of the two inclined tooth members disposed at the outer periphery are equal to each other. The width of the inclined tooth member disposed at the outer portion is half the width of the inclined tooth member disposed at the center portion.

The right transmission electrode 1430 includes a first right transmission pattern 1432 and a second right transmission pattern 1434 and is connected to the second body wiring 2412 and the second branch portions 2414 And is disposed in a shape to surround the second body wiring 2412 and the second branch portions 2414 from the other side. Since the second branch portions are branched at the obtuse angle or acute angle in the second body wiring 2412 in the present embodiment, they are formed in the first right transmission pattern 1432 and the second right transmission pattern 1434 And the groove shape surrounding the second branch portions 2414 also has an oblique shape from the observer's viewpoint. The spacing between the right transmission electrode 1430 and the second body wiring 2412 and the second branch portions 2414 may be uniform.

Specifically, the first right transmission pattern 1432 and the second right transmission pattern 1434 are formed in an inclined tooth shape to surround the second body wiring 2412 and the second branch portions 2414 .

Each of the first right transmission pattern 1432 and the second right transmission pattern 1434 includes five inclined tooth members. The widths of the three inclined tooth members disposed at the center are equal to each other and the widths of the two inclined tooth members disposed at the outer periphery are equal to each other. The width of the inclined tooth member disposed at the outer portion is half the width of the inclined tooth member disposed at the center portion.

The left routing wiring 1440 includes a first left routing wiring 1442, a second left routing wiring 1444, and a third left routing wiring 1446. Since the left routing wiring 1440 is the same as the left routing wiring 1140 described in FIG. 4, detailed description will be omitted.

The right routing wiring 1450 includes a first right routing wiring 1452 and a second right routing wiring 1454. Since the right routing wiring 1450 is the same as the right routing wiring 1150 described in FIG. 4, detailed description is omitted.

The central transmission electrode 1460 is the same as the central transmission electrode 1160 described in FIG. 4, and thus its detailed description is omitted.

Although not shown in FIG. 8, first leaf portions may be further formed in each of the first branch portions 1414 to form an inclined cross shape, as illustrated in FIG. The first left transmission pattern 1422, the second left transmission pattern 1424, and the third left transmission pattern 1426 of the left transmission electrode 1420 may be formed with tilted cross-shaped openings. Accordingly, efficiency of generating the electric field flux formed between the left transmission electrode 1420 and the left reception electrode 1410 can be increased.

The second branch portions 2414 may be further formed with second leaf portions that form an inclined cross shape. An inclined cross-shaped opening may be formed in the first right transmission pattern 1432 and the second right transmission pattern 1434 of the right transmission electrode 1430. Thus, the efficiency of generating the electric field flux formed between the right transmitting electrode 1430 and the right receiving electrode 2410 can be increased.

9 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

9, the touch sensing unit 1500 includes a left receiving electrode 1510, a right receiving electrode 2510 formed on the same layer, a left transmitting electrode 1520 disposed in the left region of the left receiving electrode 1510, A right transmission electrode 1530 disposed in the right area of the right reception electrode 2510, a left routing wiring 1540 connected to the left transmission electrode 1520, a right routing wiring 1550 connected to the right transmission electrode 1530, And a central transmitting electrode 1560 disposed between the left receiving electrode 1510 and the right receiving electrode 2510.

The left receiving electrode 1510 is divided into a first body wiring 1512 extending in a zigzag manner in a first direction D1 and a second body wiring 1512 branched in a second direction D2 at a curved portion of the first body wiring 1512 And a plurality of first branch portions 1514. The width of the first body wiring 1512 and the width of the first branch 1514 may be the same.

The right receiving electrode 2510 is connected to the second body wiring 2512 extending in a zigzag manner in the first direction D1 and the second body wiring 2512 branched at the bent portion of the second body wiring 2512 along the second direction D2 And a plurality of second branch portions 2514. The width of the second body wiring 2512 and the width of the second branch 2514 may be the same.

The left transmission electrode 1520 includes a first left transmission pattern 1522, a second left transmission pattern 1524 and a third left transmission pattern 1526, and the first body wiring 1512 and the first And is disposed at a predetermined distance from the branch portions 1514 to surround the first body wiring 1512 and the first branch portions 1514 from one side. The spacing between the left transmission electrode 1520 and the first body wiring 1512 and the first branch portions 1514 may be uniform.

The right transmission electrode 1530 includes a first right transmission pattern 1532 and a second right transmission pattern 1534. The right transmission electrode 1530 is connected to the second body wiring 2512 and the second branch portions 2514, And is disposed in a shape to surround the second body wiring 2512 and the second branch portions 2514 from the other side. The spacing between the right transmission electrode 1530 and the second body wiring 2512 and the second branch portions 2514 may be uniform.

The left routing wiring 1540 includes a first left routing wiring 1542, a second left routing wiring 1544, and a third left routing wiring 1546. Since the left routing wiring 1540 is the same as the left routing wiring 1140 described in FIG. 4, detailed description is omitted.

The right routing wiring 1550 includes a first right routing wiring 1552 and a second right routing wiring 1554. Since the right routing wiring 1550 is the same as the right routing wiring 1150 described in FIG. 4, detailed description is omitted.

The central transmission electrode 1560 extends in a zigzag manner in a first direction D1. The central transmission electrodes 1560 of each of the touch sensing units 1500 are commonly connected to each other. For example, the central transmission electrode 1560 is provided with a wake-up signal from an external capacitance sensing circuit (not shown) during a wake-up period and receives a ground voltage from the capacitance sensing circuit during the touch sensing period, . As another example, the central transmission electrode 1560 may be provided with a wake-up signal from an external capacitance sensing circuit (not shown) during the wake-up period and may remain electrically floating during the touch sensing period.

In this embodiment, although the widths of the left transmission patterns are shown to be equal to each other, the width of the left transmission patterns may gradually increase from the left transmission pad member. Accordingly, the interval between the left transmission patterns and the left routing wiring can be uniform. In addition, although the widths of the right transmission patterns are shown to be equal to each other, the width of the right transmission pattern may gradually increase as the distance from the right transmission pad member increases. Thus, the distance between the right transmission patterns and the right routing wiring can be uniform.

Although not shown in FIG. 9, the first leaf portions branched from each of the first branch portions 1514 may be further formed, as illustrated in FIG. The first left transmission pattern 1522, the second left transmission pattern 1524 and the third left transmission pattern 1526 of the left transmission electrode 1520 are further formed with openings for surrounding the first leaf portions . Thus, the efficiency of generating the electric field flux formed between the left transmission electrode 1520 and the left reception electrode 1510 can be increased.

Further, the second leaf portions branched from each of the second branch portions 2514 may be further formed. The first right transmission pattern 1532 and the second right transmission pattern 1534 of the right transmission electrode 1530 may further include openings surrounding the second leaf portions. Thus, the efficiency of generating the electric field flux formed between the right transmission electrode 1530 and the right reception electrode 2510 can be increased.

10 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

10, the touch sensing unit 1600 includes a left receiving electrode 1610, a right receiving electrode 2610, and a left transmitting electrode 1620 disposed in the left region of the left receiving electrode 1610 A right transmission electrode 1630 disposed on the right side of the right receiving electrode 2610, a left routing wiring 1640 connected to the left transmission electrode 1620, a right routing wiring 1640 connected to the right transmission electrode 1630, And a central transmitting electrode 1660 disposed between the left receiving electrode 1610 and the right receiving electrode 2610. [

The left receiving electrode 1610 includes a first body wiring 1612 extending in a wavy shape in a first direction D1 and a plurality of first branch portions 1614 branched from the first body wiring 1612 do. The width of the first body wiring 1612 and the width of the first branch portion 1614 may be the same. Although the first branch portions 1614 are shown as being branched at the middle portion between the top portion and the bottom portion in the present embodiment, the first branch portions 1614 may have a wavy shape And may be branched at the top portion and the bottom portion.

The right receiving electrode 2610 includes a second body wiring 2612 extending in a first direction D1 and a plurality of second branch portions 2614 branched from the second body wiring 2612 do. The width of the second body wiring 2612 and the width of the second branch portion 2614 may be the same. In this embodiment, the second branch portions 2614 are shown to be branched at an intermediate portion between a top portion and a bottom portion in a wavy shape, but the second branch portions 2614 are formed in a wavy shape And may be branched at the top portion and the bottom portion.

The left transmission electrode 1620 includes a first left transmission pattern 1622, a second left transmission pattern 1624 and a third left transmission pattern 1626, and the first body wiring 1612 and the first And is disposed at a predetermined distance from the branch portions 1614 so as to surround the first body wiring 1612 and the first branch portions 1614 from one side. In the present embodiment, each of the first left transmission pattern 1622, the second left transmission pattern 1624, and the third left transmission pattern 1626 has a wavy shape. The spacing between the left transmission electrode 1620 and the first body wiring 1612 and the first branch portions 1614 may be uniform.

The right transmission electrode 1630 includes a first right transmission pattern 1632 and a second right transmission pattern 1634 and is connected to the second body wiring 2612 and the second branch portions 2614 And is disposed in a shape to surround the second body wiring 2612 and the second branch portions 2614 from the other side. In the present embodiment, each of the first right transmission pattern 1632 and the second right transmission pattern 1634 has a wavy shape. The spacing between the right transmission electrode 1630 and the second body wiring 2612 and the second branch portions 2614 may be uniform.

The left routing wiring 1640 includes a first left routing wiring 1642, a second left routing wiring 1644 and a third left routing wiring 1646. The left routing wiring 1640 includes a first left routing wiring 1642, And is connected to the left transmission electrode 1620 by being disposed in an area opposite to the reception electrode 1610. The first left routing wiring 1640 is connected to the first left transmission pattern 1622 and extends to the peripheral region PA in parallel with the longitudinal direction of the body wiring 1612. The second left routing wiring 1640 is connected to the second left transmission pattern 1624 and extends to the peripheral region PA in parallel with the longitudinal direction of the body wiring 1612. The third left routing wiring 1640 is connected to the third left transmission pattern 1626 and extends to the peripheral region PA in parallel with the longitudinal direction of the body wiring 1612. In the present embodiment, each of the first left routing wiring 1640, the second left routing wiring 1640, and the third left routing wiring 1640 has a wavy shape.

The right routing wiring 1650 includes a first right routing wiring 1652 and a second right routing wiring 1654. The right routing wiring 1650 is connected to the right transmission electrode 1630 in a region opposite to the right reception electrode 2610 And is connected to the right transmission electrode 1630. The first right routing wiring 1650 is connected to the first right transmission pattern 1632 and extends to the peripheral region PA in parallel with the longitudinal direction of the body wiring 1612. The second right routing wiring 1650 is connected to the second right transmission pattern 1634 and extends to the peripheral region PA in parallel with the longitudinal direction of the body wiring 1612. [ In this embodiment, each of the first right-side routing wiring 1650 and the second right-side routing wiring 1650 has a wavy shape.

The central transmission electrode 1660 extends in a wavy manner in a first direction D1. The central transmission electrodes 1660 of the touch sensing units 1600 are commonly connected to each other. For example, the central transmission electrode 1660 may receive a wake-up signal from an external capacitance sensing circuit (not shown) during a wake-up period and may receive a ground voltage from the capacitance sensing circuit during a touch sensing period, .

As another example, the central transmission electrode 1660 may be provided with a wake-up signal from an external capacitance sensing circuit (not shown) during the wake-up period and may be electrically floated during the touch sensing period.

The ground mode in which the ground voltage is applied and the floating mode in which the electric floating state is maintained may be selected by the designer designing the touch sensing chip or may be designed to be selected by the user of the touch sensing device. For example, the ground mode may be employed when the size of the touch sensing unit 1600 is large, and the floating mode may be employed when the size of the touch sensing unit 1600 is small. Alternatively, the ground mode may be employed when the noise signal of the display panel 40 disposed at the lower portion of the touch panel 10 is large, and the floating mode may be employed when the display panel 40 Can be employed when the noise signal is small.

In this embodiment, although the widths of the left transmission patterns are shown to be equal to each other, the width of the left transmission patterns may gradually increase from the left transmission pad member. Accordingly, the interval between the left transmission patterns and the left routing wiring can be uniform. In addition, although the widths of the right transmission patterns are shown to be equal to each other, the width of the right transmission pattern may gradually increase as the distance from the right transmission pad member increases. Thus, the distance between the right transmission patterns and the right routing wiring can be uniform.

Although not shown in FIG. 10, the first leaf portions branched from each of the first branch portions 1614 may be further formed, as illustrated in FIG. The first left transmission pattern 1622, the second left transmission pattern 1624, and the third left transmission pattern 1626 of the left transmission electrode 1620 are further formed with openings surrounding the first leaf portions . Accordingly, the efficiency of generating the electric field flux formed between the left transmission electrode 1520 and the left reception electrode 1610 can be increased.

Further, it is possible to further form the second leaf portions branched from each of the second branch portions 2614. The first right transmission pattern 1632 and the second right transmission pattern 1634 of the right transmission electrode 1630 may further include openings surrounding the second leaf portions. Accordingly, the efficiency of generating the electric field flux formed between the right transmission electrode 1630 and the right reception electrode 2610 can be increased.

11 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

11, the touch sensing unit 1700 includes a left receiving electrode 1710 formed on the same layer, a right receiving electrode 2710, a left transmitting electrode 1720 disposed in the left region of the left receiving electrode 1710, A right transmission electrode 1730 disposed on the right side of the right reception electrode 2710, a left routing wiring 1740 connected to the left transmission electrode 1720, a right routing wiring 1740 connected to the right transmission electrode 1730, And a central transmitting electrode 1760 disposed between the left receiving electrode 1710 and the right receiving electrode 2710. [

The left receiving electrode 1710 includes a first body wiring 1712 extending in a first direction D1 and a plurality of first branches 1714 branched from the first body wiring 1712. [ In the present embodiment, the first branch portions 1714 are branched into a V-shape at the first body wiring 1712. The width of the first body wiring 1712 and the width of the first branch portion 1714 may be the same.

The right receiving electrode 2710 includes a second body wiring 2712 extending in a first direction D1 and a plurality of second branches 2714 branched from the second body wiring 2712. [ In the present embodiment, the second branch portions 2714 are branched into a V shape at the second body wiring 2712. The width of the second body wiring 2712 and the width of the second branch portion 2714 may be the same.

In this embodiment, the branch portions of the first branch portions 1714 and the branch portions of the second branch portions 2714 are arranged in a zigzag shape.

The left transmission electrode 1720 includes a first left transmission pattern 1722, a second left transmission pattern 1724 and a third left transmission pattern 1726, and the first body wiring 1712 and the first And is disposed so as to surround the first body wirings 1712 and the first branch portions 1714 at a predetermined distance from the branch portions 1714. The spacing between the left transmission electrode 1720 and the first body wiring 1712 and the first branch portions 1714 may be uniform.

The right transmission electrode 1730 includes a first right transmission pattern 1732 and a second right transmission pattern 1734. The right transmission electrode 1730 is connected to the second body wiring 2712 and the second branch portions 2714, And is arranged in a shape to surround the second body wiring 2712 and the second branch portions 2714 from the other side. The spacing between the right transmission electrode 1730 and the second body wiring 2712 and the second branch portions 2714 may be uniform.

The left routing wiring 1740 includes a first left routing wiring 1742, a second left routing wiring 1744, and a third left routing wiring 1746. The left routing wiring 1740 is the same as the left routing wiring 1140 described with reference to FIG. 4, and a detailed description thereof will be omitted.

The right routing wiring 1750 includes a first right routing wiring 1752 and a second right routing wiring 1754. [ Since the right routing wiring 1750 is the same as the right routing wiring 1150 described in FIG. 4, detailed description is omitted.

The central transmission electrode 1760 is the same as the central transmission electrode 1160 described in FIG. 4, and thus a detailed description thereof will be omitted.

Although not shown in FIG. 11, first leaf portions may be further formed in each of the first branch portions 1714 to form a cross shape, as illustrated in FIG. The first left transmission pattern 1722, the second left transmission pattern 1724 and the third left transmission pattern 1726 of the left transmission electrode 1720 are further formed with openings for surrounding the first leaf portions . Accordingly, the efficiency of generating the electric field flux formed between the left transmission electrode 1720 and the left reception electrode 1710 can be increased.

In addition, second leaf portions may be further formed in each of the second branch portions 2714 to form a cross shape. The first right transmission pattern 1732 and the second right transmission pattern 1734 of the right transmission electrode 1730 may further include openings surrounding the second leaf portions. Accordingly, the efficiency of generating the electric field flux formed between the right transmitting electrode 1730 and the right receiving electrode 2710 can be increased.

12 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

12, the touch sensing unit 1800 includes a left receiving electrode 1810, a right receiving electrode 2810 formed on the same layer, a left transmitting electrode 1820 disposed in the left region of the receiving electrode 1810, A right transmission electrode 1830 disposed in the right area of the reception electrode 1810, a left routing wiring 1840 connected to the left transmission electrode 1820, a right routing wiring 1850 connected to the right transmission electrode 1830, And a central transmitting electrode 1860 disposed between the left receiving electrode 1810 and the right receiving electrode 2810.

The left receiving electrode 1810 includes a first body wiring 1812 extending in a first direction D1 and a plurality of first branches 1814 branched from the first body wiring 1812. [ The width of the first body wiring 1812 and the width of the first branch 1814 may be the same.

The right receiving electrode 2810 includes a second body wiring 2812 extending in a first direction D1 and a plurality of second branches 2814 branched from the second body wiring 2812. [ The width of the second body wiring 2812 and the width of the second branch portion 2814 may be the same.

In this embodiment, the first branch portions 1814 and the second branch portions 2814 are arranged to form a V-shape. The first branch portions 1814 and the second branch portions 2814 may be arranged to form an inverted-V (or A-shaped) shape.

The left transmission electrode 1820 includes a first left transmission pattern 1822, a second left transmission pattern 1824 and a third left transmission pattern 1826, and the first body wiring 1812 and the first And is disposed at a predetermined distance from the branch portions 1814 so as to surround the first body wiring 1812 and the first branch portions 1814 from one side. The spacing between the left transmission electrode 1820 and the first body wiring 1812 and the first branch portions 1814 may be uniform.

The right transmission electrode 1830 includes a first right transmission pattern 1832 and a second right transmission pattern 1834 and is connected to the second body wiring 2812 and the second branch portions 2814 And is disposed in a shape to surround the second body wiring 2812 and the second branch portions 2814 from the other side. The spacing between the right transmission electrode 1830 and the second body wiring 2812 and the second branch portions 2814 may be uniform.

The left routing wiring 1840 includes a first left routing wiring 1842, a second left routing wiring 1844, and a third left routing wiring 1846. Since the left routing wiring 1840 is the same as the left routing wiring 1140 described in FIG. 4, detailed description is omitted.

The right routing wiring 1850 includes a first right routing wiring 1850 and a second right routing wiring 1850. Since the right routing wiring 1850 is the same as the right routing wiring 1150 described in FIG. 4, detailed description is omitted.

The central transmission electrode 1860 is the same as the central transmission electrode 1160 described in FIG. 4, and thus a detailed description thereof will be omitted.

Although not shown in FIG. 12, first leaf portions may be further formed in each of the first branch portions 1814 to form a cross shape, as illustrated in FIG. The first left transmission pattern 1822, the second left transmission pattern 1824 and the third left transmission pattern 1826 of the left transmission electrode 1820 are further formed with openings surrounding the first leaf portions . Accordingly, the efficiency of generating the electric field flux formed between the left transmission electrode 1820 and the left reception electrode 1810 can be increased.

Further, second leaf portions may be further formed in each of the second branch portions 2814 to form a cross shape. The first right transmission pattern 1832 and the second right transmission pattern 1834 of the right transmission electrode 1830 may further include openings surrounding the second leaf portions. Accordingly, the efficiency of generating the electric field flux formed between the right transmitting electrode 1830 and the right receiving electrode 2810 can be increased.

In the above embodiments, the widths of the left routing interconnections and the right routing interconnections corresponding to the transmission routing interconnections are uniform. However, as shown in FIG. 13, which will be described later, the widths of the left routing interconnections and the right routing interconnections may increase as they are away from the reception electrode.

13 is a plan view schematically illustrating a modification of the touch sensing unit according to an embodiment of the present invention.

13, the touch sensing unit 1900 includes a left receiving electrode 1110, a right receiving electrode 2110, a left transmitting electrode 1120 disposed in the left region of the left receiving electrode 1110, The right transmission electrode 1130 disposed in the right area of the right reception electrode 1110, the left routing wiring 1940 connected to the left transmission electrode 1120, the right routing wiring 1950 connected to the right transmission electrode 1130, And a central transmitting electrode 1960 disposed between the left receiving electrode 1110 and the right receiving electrode 2110.

The left receiving electrode 1110 and the right receiving electrode 2110 are the same as the left receiving electrode 1110 and the right receiving electrode 2110 described in FIG. do.

The left transmission electrode 1120 includes a first left transmission pattern 1121, a second left transmission pattern 1122, and an nth left transmission pattern 112n. The shapes and arrangements of the left transmission patterns 1121, 1122, and 112n shown in FIG. 13 correspond to shapes and arrangements of the first through third left transmission patterns 1122, 1124, and 1126 described in FIG. The detailed description thereof will be omitted.

The right transmission electrode 1130 includes a first right transmission pattern 1131 and a second right transmission pattern 1132 to an (n-1) right transmission pattern 113n-1. The shapes and arrangements of the right transmission patterns 1131, 1132, ..., and 113n-1 shown in FIG. 13 correspond to the shapes of the first and second right transmission patterns 1132 and 1134 And the detailed description thereof will be omitted.

The left routing wiring 1940 includes a first left routing wiring 1941, a second left routing wiring 1942, a third left routing wiring 1943, ..., an nth left routing wiring 194n And is connected to the left transmission electrode 1120 at a position opposite to the left reception electrode 1110 with respect to the left transmission electrode 1120. The first left routing wiring 1941 is connected to the first left transmission pattern 1122 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112. The second left routing wiring 1942 is connected to the second left transmission pattern 1124 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112. The nth left routing wiring 194n is connected to the nth left transmission pattern 1126 and extends to the peripheral region PA in parallel with the longitudinal direction of the first body wiring 1112. [ In this embodiment, the linewidths of the first to nth left routing wirings 1941, 1942, 1943, ..., and 194n increase as the distance from the left transmission electrode 1120 increases. Thus, it is possible to improve transmission characteristics of a signal transmitted to the left transmission pattern disposed in a region far from the pad portion.

The right routing wiring 1950 includes a first right routing wiring 1951, a second right routing wiring 1952, ..., (n-1) right routing wiring 194n-1, And is connected to the right transmission electrode 1130 by being disposed in a region opposite to the right reception electrode 2110 with respect to the transmission electrode 1130. The first right routing wiring 1951 is connected to the first right transmission pattern 1132 and extends to the peripheral region PA in parallel with the longitudinal direction of the second body wiring 2112. The second right routing wiring 1952 is connected to the second right transmission pattern 1134 and extends to the peripheral region PA in parallel with the longitudinal direction of the second body wiring 2112. In this manner, the (n-1) -th right-hand routing wiring 195n-1 is connected to the second right transmission pattern 1134 and is connected to the peripheral area PA in parallel with the longitudinal direction of the second body wiring 2112 . In this embodiment, the linewidths of the first through (n-1) th right routing wires 1951, 1952, ..., and 195n-1 increase as the distance from the right transmission electrode 1130 increases. As a result, it is possible to improve the transmission characteristics of the signal transmitted to the right transmission pattern disposed in the region far from the pad portion.

The central transmission electrode 1960 is the same as the central transmission electrode 1160 described with reference to FIG. 4, and a detailed description thereof will be omitted.

14 is a schematic view for explaining a touch sensing apparatus according to an embodiment of the present invention.

Referring to FIG. 14, a touch sensing apparatus according to an embodiment of the present invention includes a touch panel 10, a first capacitance sensing circuit 200, and a second capacitance sensing circuit 300. In addition, the touch sensing apparatus may further include a central processing unit (CPU) 80 and a timing control unit 90. The first and second capacitance sensing circuits 200 and 300, the central processing unit (CPU) 80, and the timing controller 90 may be implemented on one chip or on different chips.

The touch panel 10 has a touch screen area and a touch button area. For example, the touch panel 10 may be disposed between a display panel (not shown) and a transparent window (not shown). As another example, the touch panel 10 may be formed on the back surface of the transparent window and disposed on the display panel. As another example, the touch panel 10 may be formed on the upper glass of the display panel.

A plurality of touch sensing units extending in the X-axis direction and arranged in the Y-axis direction are disposed in the touch screen area. Each of the touch sensing units includes a plurality of left reception electrodes, a plurality of right reception electrodes, a plurality of left transmission electrodes, a plurality of right transmission electrodes, and a plurality of left routing wires. A plurality of right routing wires and a plurality of central transmission electrodes. The description of the above-described touch sensing units has been described in the above-mentioned embodiments and will be omitted. The left reception electrodes, the right reception electrodes, the left transmission electrodes, the right transmission electrodes, the left routing wires, the right routing wires, and the center transmission electrodes may be formed in the same layer.

In the present embodiment, the left transmission electrodes and the right transmission electrodes serve to transmit a specific signal, for example, a transmission signal of a square wave, and the left reception electrodes and the right reception electrodes are connected to the left transmission And the electrostatic capacitance due to the signals induced from the electrodes and the right transmission electrodes.

In addition, the central transmission electrodes are commonly connected to each other to receive a wake-up signal from the first capacitance sensing circuit 200 during a wake-up period, and to receive a wake-up signal from the first capacitance sensing circuit 200 during a touch sensing period Ground voltage is provided. At this time, the left receiving electrodes and the right receiving electrodes detect the capacitances due to signals induced from the central transmitting electrodes.

Meanwhile, the central transmission electrodes are commonly connected to each other to receive a wake-up signal from the first capacitance sensing circuit 200 during a wake-up period and to receive a wake-up signal from the first capacitance sensing circuit 200 during a touch sensing period No signal is provided, and it is possible to maintain an electrically floating state.

A plurality of touch buttons TB1 and TB2 and sense lines connected to the touch buttons TB1 and TB2 are disposed in the touch button area. In Fig. 14, the left touch button TB1 corresponds to the feedback to the groove, and the right touch button TB2 corresponds to the feedback to the previous screen.

The connection between the touch panel 10 and the first capacitive sensing circuit 200 and the second capacitive sensing circuit 300 may be via a circuit board.

15 is a schematic view for explaining the circuit board shown in Fig.

14 and 15, the wiring connecting member WCM has a side connected electrically to the touch panel 10 and a side connected to a circuit board (not shown) on which the touch sensing chip is mounted. In the touch sensing chip, a first capacitance sensing circuit 200, a second capacitance sensing circuit 300, and the like may be integrated.

The wiring connection member WCM may be a flexible printed circuit board (FPCB), or another flexible circuit board may be used. The wiring connection member WCM may be disposed at one end of the touch sensing area 140. The wiring connection member WCM may be electrically connected to a pad portion formed on the touch panel 10.

The wiring connection member WCM may be attached to one surface of the touch panel 10. For example, the wiring connection member WCM may be attached to one surface of the touch panel 10 through processes such as ACF (Anisotropic Conductive Film), ACP (Anisotropic Conductive Paste), ACA (Anisotropic Conductive Adhesive) , And an ultrasonic bonding process may be used in the bonding process. In some embodiments, the wiring connection member WCM is about 70? To 150? By using ACF or the like.

The wiring connection member WCM may be formed with wiring for transferring a driving signal to the transmission line and receiving a sensing signal from the reception electrode. R1, R2, R3, R4, R5, ..., Rn, ..., Rn denote wires for transmitting drive signals to the transmission lines, -1 and Rn are the wirings receiving the sense signal from the receive line. For example, the wiring corresponding to each of the reference signs T1, ..., T7 is connected to each of the first left transmission pattern, the second left transmission pattern, and the third left transmission pattern included in the touch sensing units, . The wiring corresponding to each of the reference symbols T2, ..., T8 is connected to the first right transmission pattern and the second right transmission pattern provided in the touch sensing units to transmit the driving signal. In this embodiment, the wiring corresponding to T0 is connected in common to the central transmission electrodes to transmit a wake-up signal to the central transmission electrodes during the wake-up interval, To the transmitting electrodes. On the other hand, the wiring corresponding to T0 is commonly connected to the central transmission electrodes to transmit a wake-up signal to the central transmission electrodes during the wake-up interval, and during the touch sensing interval, It may not provide any signal to be used.

With respect to the wiring of the wiring connection member WCM, each of the wiring connection members WCM includes a first layer having a plurality of wirings, an insulating layer covering the first layer, a plurality of wirings And the wirings of the first layer and the wirings of the second layer may be electrically connected through via holes.

In the wiring connection member (WCM), the wirings formed in the first layer may be electrically connected to the pad portion of the touch panel (10). In the wiring connection member (WCM), the wirings formed in the second layer may be electrically connected to a circuit substrate on which the touch sensing chip or the touch sensing chip is mounted. In the touch sensing chip, a first capacitance sensing circuit 200, a second capacitance sensing circuit 300, and the like are integrated.

In general, a printing process such as sputtering, etching fixation, and silk screen, which is a process of forming a wiring, is performed in comparison with processes such as ACF (Anisotropic Conductive Film), ACP (Anisotropic Conductive Paste) and ACA (Anisotropic Conductive Adhesive) The yield is low. Therefore, by attaching the wiring connecting member WCM, on which the wiring is printed in advance, to the touch panel 10 instead of directly printing the wiring on the bezel area of the touch panel 10, the process of the touch sensing device can be simplified, Can be improved.

In addition, since the wiring connecting member WCM is replaced with a wiring directly formed on the touch panel 10, the step of forming the insulating layer for protecting the wiring on the touch panel 10 can be omitted, Can be simplified.

The wiring connection member WCM may be a flexible circuit board. Therefore, the area of the bezel area where the wiring is formed is reduced, the wiring connecting member WCM printed with the wiring is bonded to the touch panel 10, and the wiring connecting member WCM is moved toward the rear side of the touch panel 10 If folded, the bezel width can be reduced overall, thereby reducing the overall size of the substrate, or reducing the bezel width in a substrate of the same size, thereby enabling image display on a larger screen .

In the present embodiment, the wiring connecting member WCM electrically connects the touch panel 10 on which the touch sensing units are formed to the circuit board on which the touch sensing chip is mounted. However, the touch sensing chip may be directly mounted or mounted on the wiring connecting member WCM.

In the following description, the left transmission electrode and the right transmission electrode described in the above embodiments are collectively referred to as transmission lines.

Referring again to FIG. 14, the first capacitance sensing circuit 200 includes a current mirror-based charge integration circuit and is connected to the transmission lines and the reception electrodes disposed in the touch screen region, Detects the difference between the capacitances generated between the transmission line and the reception electrode and detects whether or not the touch is detected. The first capacitance sensing circuit 200 includes a transmission circuit 210 and a reception circuit 220.

The transmission circuit unit 210 includes a transmitter 212 and a transmission switch 214. The transmission circuit unit 210 transmits the transmission signal in response to the first switching control signal S1 provided from the timing controller 90 to the touch panel 10 To the transmission lines of the transmission line. In this embodiment, the transmitter 212 outputs a square wave transmission signal to the transmission lines of the touch panel 10. The intensity of the transmission signal output from the transmitter 212 may be weak. If the intensity of the transmitted signal is weak, it may be difficult to process the signal in the receiving circuit 220. Therefore, by increasing the output voltage of the transmitter 212 and increasing the transmission energy, the amount of energy induced in the receiving electrode can be further increased. The transmission circuit unit 210 may further include a power booster (not shown) such as a charge pump to increase the voltage of the transmission signal. In this embodiment, the transmitter 212 applies a wake-up signal to the central transmitting electrode during the wake-up interval of the touch sensing device. In addition, the transmitter 212 applies a ground voltage to the central transmission electrode during a touch sensing period of the touch sensing apparatus. Meanwhile, the transmitter 212 may control the central transmission electrode to be electrically floated during the touch sensing period of the touch sensing apparatus.

The receiving circuit unit 220 includes a receiving switch 222, a resistor unit 224, a first charge integrator circuit 226 and an analog-to-digital converter 228, And detects the difference in electrostatic capacitance generated between the receiving electrodes from the receiving electrode of the touch panel (10). That is, the first capacitance sensing circuit 200 operates in a mutual-capacitance mode to detect a touch. The mutual-capacitance mode will be described as follows. In the touch sensing through the mutual-capacitance mode, a specific signal is applied to a transmission line and a capacitance component due to a signal induced through the reception electrode is sensed to detect whether a touch is generated.

The receiving switch 222 connects one of the receiving electrodes of the touch panel 10 and the variable resistance generating unit 224 to each other and outputs the receiving signal RX transmitted through the receiving electrode to the variable resistance generating unit 224.

The variable resistance generating unit 224 lowers the potential of the reception signal RX input through the reception switch 222 and provides the received signal RX to the first charge integrating circuit 226. The variable resistance generator 224 may include a variable resistor. In addition, the variable resistance generator 224 may include a serial resistor.

The first charge integration circuit 226 may be configured based on a current mirror. The first charge integration circuit 226 integrally integrates charges corresponding to the rising period and the falling period of the transmission signal of the square wave applied from the transmission circuit unit 210, And detects whether or not the touch is detected. In the present embodiment, the receiving circuit 220 is provided with the receiving switch 222 to receive the receiving signal from the receiving electrode. However, the receiving switch 222 may be omitted. At this time, a plurality of the receiving circuit units 222 are provided and connected to the receiving electrodes, respectively.

Since the variation width of the received signal (charge amount) detected due to the contact of the human body is very small, such as several tens of fF to several Pf, the charge integrator for accumulating the charge due to the received signal and amplifying the accumulated charge into voltage, : 226) are used in the receiving circuit unit 220. And an analog-to-digital converter (ADC) 228 for digitizing the value of the detected voltage for data processing.

The second capacitance sensing circuit 300 includes a sensing switch 310 and a second charge integrating circuit 320 and is connected to the sensing lines connected to the respective button patterns TB1 and TB2 of the touch button region And checks on / off of the button patterns TB1 and TB2 through the sensing lines to detect whether or not the touch pattern is touched. The sensing switch 310 connects the sensing lines connected to the button pattern and the second charge integration circuit 320 to each other. The second charge integration circuit 320 may be configured based on a current mirror. The second charge integration circuit 320 detects the touch of the button pattern by detecting the capacitance of the button pattern. For example, when a user's human touch is generated, the capacitance of the button pattern is changed and contact is detected through comparison with the capacitance before contact. That is, the second capacitance sensing circuit 300 operates in a self-capacitance mode to sense a touch. The self-capacitance mode will be described as follows. In the touch sensing through the self-capacitance mode, a sensing signal is independently applied to sensing patterns, and a change amount of a sensing signal itself, which is deformed from a touch action of a user, is measured using the same signal line, .

According to the present invention, when a capacitance sensing circuit including a current mirror-based charge integration circuit is employed in a touch sensing device, the capacitance sensing circuit is operated in a combined mode driven in a self-capacitance mode and a mutual-capacitance mode To illustrate, a variable resistance generator is added to the capacitive sensing circuit that performs the mutual-capacitance mode. However, a mutual-capacitance mode may be implemented without adding a separate variable resistance generator.

That is, W / L (W is the channel width and L is the channel length) of the transistor provided at the input terminal of the first charge integrating circuit 226 included in the first capacitance sensing circuit 200 is connected to the second capacitance integration circuit A mutual capacitance mode can be realized by designing the second charge integration circuit 320 to be smaller than the W / L of the transistor provided at the input terminal of the second charge integration circuit 320 included in the charge integration circuit 300.

As described above, according to the touch sensing apparatus, the capacitances between adjacent transmission lines and reception electrodes are separated from each other, and at the same time, an electric energy field generated from the transmission signal of the transmission line, A certain level of energy is induced to the receiving electrode. At this time, when a touch is generated by the user, a transmission signal applied to the transmission electrodes corresponding to the points where the touch is generated and a reception signal induced on the reception electrodes are formed by capacitive (Capacitance) and a change of a static / electric energy field occur, and a change in the amount of energy induced in the receiving electrode occurs.

The capacitance sensing circuit according to the present invention converts electrical energy detected from a receiving electrode, that is, the amount of charge (or the amount of change in capacitance) into a unit of voltage, and uses the difference in voltage between when the touch is generated and when it is not, It is determined whether or not the user touches. By measuring the differences in the amount of charge due to such a change in electrostatic capacitance and arranging the measured values two-dimensionally, the multi-points can be easily discriminated.

FIG. 16 is an equivalent circuit diagram schematically illustrating an example of the electrostatic capacitance sensing circuit for a touch panel of the mutual-capacitance type shown in FIG. 17 is a waveform diagram for explaining the operation of the capacitance sensing circuit shown in Fig.

16 and 17, the transmission circuit 210 connected to the touch panel 10 (shown in FIG. 14) includes a first switch SW0, a second switch SW1, a first inverter IN1, 2 inverter IN2 and provides a square wave transmission signal TX to the touch panel 10. [ For convenience of explanation, a transmitter 212 (shown in FIG. 14) provided in the transmission circuit unit 210 and outputting a transmission signal of a square wave is represented by a first switch SW0 and a second switch SW1. That is, when the first switch SW0 is turned on, the power supply voltage VDD at the high level is output, and when the second switch SW1 is turned on, the ground voltage GND at the low level is output. Therefore, a transmission signal of a square wave having a high level and a low level can be output.

The receiving circuit unit 220 includes an upper switch SW11, a lower switch SW12, an upper current mirror unit UCM, a lower current mirror unit LCM, an output switching unit SW13, an output capacitor C1, (SW14).

In response to the first and second transmission switch control signals S0 and S1 and the first and second integration control signals CP and CN in each cycle of the transmission signal TX having a square wave form, The operation of the capacitance sensing circuit at the rising edge of the TX and the operation of the capacitance sensing circuit at the falling edge are different. In this embodiment, the first transmission switch control signal S0 and the first integration control signal CP are in phase with each other.

That is, in the rising edge of the transmission signal TX, a first current path is formed along the first switch SW0, the touch panel 10, the lower switch SW12, and the lower current mirror portion LCM, 1 current path is mirrored to the NMOSs disposed on the right side of the lower current mirror portion LCM, a second current path is formed along the upper current mirror portion UCM and the lower current mirror portion LCM. The current flowing along the second current path is mirrored to the PMOSs disposed on the right side of the upper current mirror portion UCM to form a third current path along the upper current mirror portion UCM and the output switching portion SW13 . The charge corresponding to the current according to the third current path is charged to the output capacitor C1 and then output through the output terminal. Here, the received signal RX is discharged through the lower current mirror portion LCM, and thus has a voltage level that decreases with time.

On the other hand, at the falling edge of the transmission signal TX, a first current path is formed along the upper current mirror portion UCM, the upper switch SW11, the touch panel 10, and the second switch SW1. The current flowing through the left PMOSs of the upper current mirror portion UCM is mirrored to the right PMOSs of the upper current mirror portion UCM to form the second current path. The charge corresponding to the current according to the second current path is charged to the output capacitor C1 and then output through the output terminal. Here, the received signal RX has a voltage level that increases with time since the charge is continuously supplied from the upper current mirror unit UCM.

Thus, by being able to integrate the charge received at each of the rising and falling edges of the transmit signal TX, it is possible to integrate twice the charge energy compared to the technique of integrating only the charge received at the rising edge.

On the other hand, when a touch is generated during a rising edge interval or a falling edge interval of the transmission signal TX, the electrostatic capacitance C0 formed on the touch panel 10 decreases. That is, since the waveform of the transmission signal TX and the waveform of the reception signal RX are opposite to each other, the capacitance of the capacitor caused by the contact of the human body reduces the capacitance formed on the touch panel 10.

On the other hand, according to the present embodiment, the discharge path is constituted by the reception signal RX corresponding to the charging of the transmission signal TX, or the reception signal RX is charged together in response to the charging of the transmission signal TX, The sensing speed of the capacitance can be increased by increasing or decreasing the amount of charge transferred to both ends of the capacitor C0 formed on the touch panel 10 in a short period of time. That is, when one end charges the charge through the other end of the capacitor connected to the ground electrode, the charge is rapidly charged at the initial stage of charging, but the charging speed is slowed after a predetermined time has elapsed. However, when one end and the other end of the capacitor are respectively used as the charging terminal and the discharging terminal, and the one end and the other end of the capacitor are respectively used as the charging terminal and the charging terminal, the rate at which electric charges flow during charging and discharging operations is accelerated. Therefore, according to the present embodiment, it is possible to increase the sensing speed of the capacitance.

Further, according to the present invention, the configuration of the charge integration circuit for integrating both the rising period and the falling period of the transmission signal is constituted by a current mirror instead of the operational amplifier (OP-AMP), thereby simplifying the circuit configuration. In addition, it is possible to precisely maintain the voltage value in the change component of the output voltage after integration according to integration in both the rising period and the falling period of the transmission signal.

18 is a schematic view for explaining a touch sensing apparatus according to another embodiment of the present invention.

Referring to FIG. 18, a touch sensing apparatus according to another embodiment of the present invention includes a touch panel 10 and a capacitance sensing circuit 600.

The touch panel 10 has a touch screen area. A plurality of touch sensing units extending in the X-axis direction and arranged in the Y-axis direction are disposed in the touch screen area. Each of the touch sensing units includes a plurality of left reception electrodes, a plurality of right reception electrodes, a plurality of left transmission electrodes, a plurality of right transmission electrodes, and a plurality of left routing wires. A plurality of right routing wires and a plurality of central transmission electrodes. The description of the above-described touch sensing units has been described in the above-mentioned embodiments and will be omitted.

The left reception electrodes, the right reception electrodes, the left transmission electrodes, the right transmission electrodes, the left routing wires, the right routing wires, and the center transmission electrodes may be formed in the same layer.

In the present embodiment, the left transmission electrodes and the right transmission electrodes serve to transmit a specific signal, for example, a transmission signal of a square wave, and the left reception electrodes and the right reception electrodes are connected to the left transmission And the electrostatic capacitance due to the signals induced from the electrodes and the right transmission electrodes.

In addition, the central transmission electrodes are commonly connected to each other to receive a wake-up signal from the first capacitance sensing circuit 200 during a wake-up period, and to receive a wake-up signal from the first capacitance sensing circuit 200 during a touch sensing period Ground voltage is provided. At this time, the left receiving electrodes and the right receiving electrodes detect the capacitances due to signals induced from the central transmitting electrodes.

Meanwhile, the central transmission electrodes are commonly connected to each other to receive a wake-up signal from the first capacitance sensing circuit 200 during a wake-up period and to receive a wake-up signal from the first capacitance sensing circuit 200 during a touch sensing period It may maintain an electrically floating state where no signal is provided.

The connection between the touch panel 10 and the capacitance sensing circuit 600 may be performed through a wiring connection member WCM. The wiring connection member WCM is similar to the wiring connection member WCM described in FIG. 15, and therefore, a detailed description thereof will be omitted.

The capacitance sensing circuit 600 includes a current mirror-based charge integration circuit and is connected to the transmission lines and the reception electrodes disposed in the touch screen area. The capacitance sensing circuit 600 operates in a self-capacitance mode at the beginning of a touch operation, And operates in the mutual-capacitance mode as the touch is sensed.

The capacitance sensing circuit 600 includes a transmission circuit unit 610 and a reception circuit unit 620. The transmission circuit unit 610 and the reception circuit unit 620 may be formed on one chip or on different chips. Meanwhile, the transmission circuit unit 610 and the reception circuit unit 620 may be integrated on the touch panel 10.

The transmission circuit unit 610 includes a transmitter 612 and a transmission switch 614 and successively applies a transmission signal to the transmission lines of the touch panel 10 to the transmission line. In this embodiment, the transmitter 612 outputs a square wave transmission signal to the transmission lines of the touch panel 10. The intensity of the transmission signal output from the transmitter 612 may be weak. If the intensity of the transmitted signal is weak, it may be difficult to process the signal in the receiving circuit unit 620. Therefore, it is possible to increase the amount of energy induced in the receiving electrode by increasing the output voltage of the transmitter 612 to increase the transmission energy. The transmission circuit unit 210 may further include a power booster (not shown) such as a charge pump to increase the voltage of the transmission signal. In this embodiment, the transmitter 612 applies a wake-up signal to the central transmitting electrode during the wake-up interval of the touch sensing device. Also, the transmitter 612 applies a ground voltage to the central transmission electrode during a touch sensing period of the touch sensing device.

As another example, the transmitter 612 may control the central transmission electrode to be electrically floated during a touch sensing interval of the touch sensing device.

The receiving circuit unit 620 includes a receiving switch 622, a receiving electrode coupler 624, a charge integration circuit 626 and an analog-to-digital converter 628. The receiving circuit unit 620 operates in a self- And operates in the mutual-capacitance mode as the touch is sensed.

The reception switch 622 connects one of the reception electrodes of the touch panel 10 and the charge integration circuit 626 to each other and outputs a reception signal RX transmitted through the reception electrode to the charge integration circuit 626, respectively.

The receiving electrode coupler 624 couples the receiving electrodes to one signal line and provides the summed voltage (Vsum) flowing through the coupled signal line to the analog-to-digital converter 628.

The charge integration circuit 626 may be configured based on a current mirror. The charge integration circuit 626 integrates the charges corresponding to the rising period and the falling period of the transmission signal of the square wave to provide the integrated voltage Vint to the analog-to-digital converter 628. The analog-to-digital converter 628 converts the integral voltage Vint into a digital signal.

According to the present invention, the receiving electrodes are coupled to one signal line by the receiving electrode coupler 624 at the beginning of the touch operation and are connected to the analog-to-digital converter 628. At this time, the touch sensing apparatus is operated in the self-capacitance mode to detect whether it is touched. As the touch is detected, the touch sensing apparatus operates in a mutual-capacitance mode to detect a difference in capacitance between the transmission line and the reception electrode from the reception electrode of the touch panel 10. That is, the capacitance sensing circuit 600 operates in a mutual-capacitance mode to detect a touch. Accordingly, the self-capacitance mode is operated in a short sensing period at the beginning of the touch operation. When the touch is sensed, the touch sensing operation is performed in the mutual-capacitance mode.

The capacitance sensing circuit 600 may further include a timing generator 90 and a central processing unit 80.

The timing generator 90 provides the first timing signal S1 to the transmission switch 614 to control the output path of the transmission signal TX and outputs the second timing signal S2 to the reception switch 622 And controls the input path of the received signal RX and controls the coupling of the received signal RX by providing the third timing signal S3 to the receiving electrode coupler 624. [ The third timing signal S3 may be output at the beginning of the touch operation.

The central processing unit (CPU) 80 detects touch coordinates based on the digital-converted integrated voltage Vint provided from the analog-to-digital converter 628.

The timing generating unit 90 and the central processing unit 80 may be formed on one chip or on different chips. Meanwhile, the timing generating unit 90 and the central processing unit 80 may be mounted on the touch panel 10 or may be integrated.

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.

10: touch panel 20: circuit board
30: transparent window 40: display panel
200: first capacitance sensing circuit 300: second capacitance sensing circuit
WCM: wiring connecting member 210, 610:
220, 620: receiving circuit section 222: receiving switch
224: Variable resistance generator 600: Capacitive sensing circuit
612: Transmitter 614: Transmission switch
622 Receive switch 624 Receive line coupler
626: Charge integration circuit 628: Analog-to-digital converter
1100, 1200, 1300, 1400, 1500, 1600, 1700, 1800, 1900: Touch sensing unit
1110, 1210, 1310, 1410, 1510, 1610, 1710, 1810:
2110, 2210, 2310, 2410, 2510, 2610, 2710, 2810:
1120, 1220, 1320, 1420, 1520, 1620, 1720, 1820:
1130, 1230, 1330, 1430, 1530, 1630, 1730, 1830:
1160, 3160, 1260, 1360, 1460, 1560, 1660, 1760, 1860:
1140, 1240, 1340, 1440, 1540, 1640, 1740, 1840, 1940: Left routing wiring
1150, 1250, 1350, 1450, 1550, 1650, 1750, 1850, 1950:
1122, 1222, 1322, 1422, 1522, 1622, 1722, 1822:
1124, 1224, 1324, 1424, 1524, 1624, 1724, 1824:
1126, 12266 1326, 1426, 1526, 1626, 1726, 1826: the third left transmission pattern
1132, 1232, 1332, 1432, 1532, 1632, 1732, 1832:
1134, 1234, 1334, 1434, 1534, 1634, 1734, 1834: the second right transmission pattern

Claims (22)

delete A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein the left receiving electrode further includes a plurality of first leaf portions branched from each of the first branch portions. Touch panel. The touch panel of claim 2, wherein the first branch portion and the first leaf portion form a cross shape. A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein the right receiving electrode further includes a plurality of second leaf portions branched from each of the second branch portions. Touch panel. The touch panel according to claim 4, wherein the first branch portion and the second leaf portion form a cross shape. delete delete A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein the first branch portion and the second branch portion are arranged in a staggered manner. A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein the first body wiring and the first branch are orthogonal,
Wherein the second body wiring and the second branch portion are orthogonal to each other. delete A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein each of the first and second body wirings extends in a zigzag shape,
Wherein the first branch portion is branched at an inflection portion of the first body wiring, and the second branch portion is branched at an inflection portion of the second body wiring. A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein the first branch portion branches in a V shape in the first body wiring,
And the second branch portion branches in a V-shape in the second body wiring. A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring, wherein each of the first and second body wirings extends in a wavy shape,
The first branch portion branches toward the left transmission electrode at an intermediate portion between the top portion and the bottom portion of the wavy shape,
And the second branch portion is branched toward the right transmission electrode at an intermediate portion between the wave-like top portion and the bottom portion. A touch panel including a touch sensing area and a peripheral area surrounding the touch sensing area, the touch panel including a plurality of touch sensing units formed in the touch sensing area; And
And a circuit board disposed at one end of the touch sensing area for sensing capacitance in the touch sensing units,
A left receiving electrode including a first body wiring and a plurality of first branches branched from the first body wiring;
A right receiving electrode including a second body wiring parallel to the first body wiring and a plurality of second branches branched from the second body wiring;
A left transmission electrode including a plurality of left transmission patterns arranged in a shape surrounding the first body wiring and the first branch portions;
A right transmission electrode disposed in a shape surrounding the second body wiring and the second branch portions and including a plurality of right transmission patterns staggered with each of the left transmission patterns; And
And a central transmission electrode disposed between the first body wiring and the second body wiring. 15. The touch sensing apparatus of claim 14, wherein the central transmission electrodes of each of the touch sensing units are commonly connected to each other. 15. The electro-optical device according to claim 14, wherein the circuit board has capacitances connected to the left receiving electrodes, the right receiving electrodes, the left transmitting electrodes, the right transmitting electrodes, Sensing circuit,
The electrostatic capacitance sensing circuit includes a current mirror circuit based on a current mirror. The electrostatic capacitance sensing circuit operates in a self-capacitance mode at the beginning of a touch operation and senses a touch. When a touch is sensed, the electrostatic capacitance sensing circuit operates in a mutual- Wherein the touch sensing device comprises: 17. The touch sensing device of claim 16, wherein the capacitive sensing circuit applies a wake-up signal to the central transmission electrode during a wake-up interval of the touch sensing device. 17. The touch sensing apparatus of claim 16, wherein the capacitance sensing circuit applies a ground voltage to the central transmission electrode during a touch sensing period of the touch sensing apparatus. 19. The method of claim 18, wherein when a ground voltage is applied to the central transmission electrode,
The left receiving electrode receives a voltage induced in the left transmission patterns,
And the right receiving electrode receives a voltage induced in the right transmission patterns. 17. The touch sensing device of claim 16, wherein the capacitive sensing circuit controls the central transmission electrode to maintain an electrically floating state during a touch sensing period of the touch sensing device. 21. The method of claim 20, wherein when the central transmission electrode is electrically floated,
The left receiving electrode receives a voltage induced in the left transmission patterns and a voltage induced in the right transmission patterns,
Wherein the right receiving electrode receives a voltage induced in the right transmission patterns and a voltage induced in the left transmission patterns. 17. The electrostatic capacitance sensing circuit according to claim 16,
A transmission circuit connected to each of the transmission electrodes, for applying a square wave transmission signal to the transmission electrode; And
And a reception circuit unit connected to each of the reception electrodes and receiving a square wave reception signal through the reception electrode,
The receiving circuit unit,
A receiving switch for connecting any one of the receiving electrodes and the charge integrator circuit to each other to provide a received signal transmitted through the receiving electrode to the charge integrator circuit; And
And a receiving electrode coupler coupling the receiving electrodes to one signal line and outputting a sum voltage flowing through the coupled signal line.

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