KR101500330B1 - Touch panel - Google Patents

Abstract

The present invention relates to a touch panel, and more particularly, to a touch panel, in which a plurality of touch sensor nodes are arranged in a column direction to form a sensor array, and a plurality of sensor arrays matrix; A plurality of first node electrode lines connected to each pair of touch sensor nodes, each of the touch sensor nodes being classified into a pair of touch sensor nodes; And a touch sensor node included in the one sensor row is classified into a touch sensor node pair so that the touch sensor node is different from the touch sensor node pair connected to the first node electrode line, And a second node electrode line. According to the present invention, the number of electrode lines can be minimized while forming an electrode line connecting the touch sensor and the touch sensor on one plane, A touch panel can be provided.

Description

Touch panel {Touch panel}

The present invention relates to a touch panel, and more particularly, to a touch panel, in which two touch sensor nodes on a touch sensor node matrix are classified into a pair and touch sensor nodes of different touch sensor node pairs are connected to a first node electrode line, A structure of a node electrode line connected to a line and a structure of a wiring electrode line in which the first node electrode line and the second node electrode line are connected so as to minimize the number of electrode lines, To a touch panel.

In recent years, touch screens have become more meaningful than user interfaces. Touch interface technology is not a new technology but a technology that has been applied to existing display products such as navigation, bank unattended ATM devices, POS used in general stores such as marts and restaurants.

The use of touch in these products was an interface that allows immediate and simple input without a keyboard or mouse. The biggest advantage was that all ages can input without inconvenience. Of course, I focused on the simple function of On / Off. Touch interface technology has entered a new era when Apple added touch functions to its mobile phone with multi touch and soft touch functions. As the display screen is easily enlarged and reduced while the multi-touch function is added, the usability of the mobile phone is improved. In addition, the application is easy to use, and the soft touch technology is combined with the emotional function to recognize and express the user's behavior.

Currently, the touch panel technology that is most commonly used in mobile phones is a projected capacitive type. In a projection type capacitive touch panel, a transparent conductive film in which an X-axis sensing electrode is formed and a Y-axis sensing electrode The formed transparent conductive film is assembled with an OCA (Optically Clear Adhesive) film to manufacture a touch panel, and the manufactured touch panel is attached to a mobile window substrate to produce a product.

1 is a schematic view of a projected capacitive touch panel.

The projection-type capacitive touch panel uses two or three conductive transparent conductive films, two of which are used to recognize the coordinates of X and Y, and one is used to remove noise, which is particularly common in mobile products.

Fig. 2 shows a pattern shape of a projection type capacitance method generally used.

Although the pattern of the touch sensor is generally formed in a rhombus shape, the touch sensor 20 can be manufactured in various shapes. In FIG. 2, the X-axis sensor 21 and the Y- Are arranged at regular intervals and arranged in a lattice to form a touch panel.

The projection-type capacitive touch panel thus manufactured is a principle in which the controller 30 includes a driving chip and an algorithm, and detects the change in minute charge when the user's hand touches the touch panel.

The touch sensor 20 and the controller 30 are connected to each other through a bezel electrode line 10 formed in the edge connection of the touch panel. FIG. 2 shows an upper surface of the touch panel. The plurality of bezel electrode lines 11a,. And a plurality of bezel electrode lines are connected to the Y-axis sensor 20 on the lower surface of the touch panel, although not shown in FIG. 2, Electrode lines, respectively.

Since the X-axis electrode line and the Y-axis electrode line connected to the X-axis sensor 21 and the Y-axis sensor 23 are insulated from each other, the touch panel according to the related art is divided into two different layers, And an insulating layer is formed on the overlapping portion. As a result, various processes for forming a multi-layered structure are required, resulting in an increase in the number of manufacturing steps and a corresponding increase in manufacturing cost.

3 shows a touch panel of a single-layer structure according to the related art in which an X-axis sensor 21 and a Y-axis sensor 23 are provided on a single-layer section and X-axis sensors 21 Axis sensor 23 are connected to each other to form one Y-axis electrode 15. The touch panel of the single-layer structure according to the related art has a structure in which the influence of an electric field generated between adjacent electrode lines There is a problem in that an error is recognized that the other sensor that is not touched in addition to the sensor actually touched by the user is caused to be touched by the user or that the touched sensor is not recognized well.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a touch sensor which can improve the touch accuracy while minimizing the number of electrode lines while forming an electrode line connecting the touch sensor and the touch sensor on one plane It is a main object to provide an electrode line of a touch sensor.

Particularly, in order to insulate the X-axis electrode line and the Y-axis electrode line connected to the X-axis sensor and the Y-axis sensor, the electrode line is divided into two different layers or a structure in which an insulating layer is formed on the overlapped portions Thereby increasing the number of manufacturing processes and increasing manufacturing costs.

In addition, in the touch panel of a single layer structure, due to the influence of an electric field generated between adjacent electrode lines, an error is recognized in which a sensor other than a sensor actually touched by a user is recognized as being touched, Thereby solving the problem of sensitivity deterioration.

According to an aspect of the present invention, there is provided a touch panel, comprising: a plurality of touch sensor nodes arranged in a column direction to form a sensor array; a plurality of sensor arrays A touch sensor node matrix configured to be configured; A plurality of first node electrode lines connected to each pair of touch sensor nodes, each of the touch sensor nodes being classified into a pair of touch sensor nodes; And a touch sensor node included in the one sensor row is classified into a touch sensor node pair so that the touch sensor node is different from the touch sensor node pair connected to the first node electrode line, And a second node electrode line.

Preferably, node electrode lines of the same kind among the first node electrode line and the second node electrode line are formed to connect adjacent sensor lines between the sensor lines, Two first touch sensor nodes may be classified into a pair of touch sensor nodes and a second node electrode line may be connected.

Furthermore, the first first node electrode lines connected to the two adjacent sensor lines in which the first node electrode lines are formed between the sensor rows may be connected to each other to form one first node electrode line.

One first node electrode line formed by connecting the first first node electrode lines connected to two adjacent sensor lines in which the first node electrode lines are formed between sensor rows is formed along the bezel region of the touch panel And a second first node electrode line connected to the two sensor lines may be connected to each other to form a first node electrode line.

A plurality of first wiring electrode lines connected to the plurality of first node electrode lines connected to one sensor line so as to be alternately connected to each other; And a plurality of second wiring electrode lines, each of which is connected in sequence with a plurality of second node electrode lines formed between the sensor rows, wherein the second wiring electrode lines are connected to a second The node electrode lines may be connected to each other

A plurality of first wiring electrode lines connected to each other such that a plurality of first node electrode lines connected to one sensor line are alternately connected to each other; And a plurality of second wiring electrode lines connected in sequence with a plurality of second node electrode lines formed between adjacent sensor rows, wherein the second node electrode lines are connected in series between the sensor rows, The second node electrode line of the reverse order formed between the two-node electrode line and another sensor line adjacent thereto may be connected to each other.

A first wiring electrode line connected to the plurality of first node electrode lines formed outside the adjacent two sensor lines according to a sequential order connected to each sensor row; And a plurality of second wiring electrode lines for connecting the plurality of second node electrode lines connected to one sensor line alternately to each other.

Furthermore, the touch sensor node according to the present invention includes: a first sensor node pattern formed by projecting a plurality of branches radially from a center; And a second sensor node pattern spaced apart from the first sensor node pattern by a predetermined distance to surround an outer periphery of the first sensor node pattern corresponding to an outer shape of the first sensor node pattern, The first sensor node pattern may be connected to one of the electrode line and the second node electrode line, and the second sensor node pattern may be connected to the other.

Or the touch sensor node includes: a second sensor node pattern formed by a plurality of arrow shapes rotated from the outer edge to the center by a predetermined angle; And a first sensor node pattern spaced apart from the second sensor node pattern by a predetermined distance and corresponding to a plurality of arrow shapes of the second sensor node pattern, The first sensor node pattern may be connected to one and the second sensor node pattern may be connected to the other.

According to the present invention, it is possible to provide a touch panel capable of improving touch accuracy while minimizing the number of electrode lines while forming an electrode line connecting the touch sensor and the touch sensor on one plane.

In particular, since the touch sensor node and the electrode line connecting them to the driving circuit can be formed on one plane by a simple process, it is divided into a conventional X-axis electrode line and a Y-axis electrode line, The number of manufacturing steps is increased and the manufacturing cost is accordingly increased due to the structure in which the insulating layer is formed on the part where the two layers are formed or overlapped with each other.

In addition, the number of electrode lines is minimized by dividing the touch sensor nodes into pairs while forming individual electrode lines for each touch sensor node, so that the X-axis sensors in the same row direction are connected to each other by the same X-axis electrode line, The Y-axis sensors of the Y-axis are connected to each other by the same Y-axis electrode line. Therefore, it is possible to eliminate the problem that an error that is recognized by the user as touching other sensors .

In addition, according to the form of the sensor node proposed in the present invention, the node pads are dispersed evenly over the entire surface, so that when the user touches the end of the touch sensor node or touches the center, The reliability of the touch sensor can be increased.

1 is a schematic view of a projected capacitive touch panel,
Fig. 2 shows a pattern shape of a projection type capacitance system generally used,
3 shows a touch panel of a single layer structure according to the prior art,
4 shows a first embodiment of a touch panel according to the present invention,
FIG. 5 illustrates an embodiment of a node electrode line connecting a touch sensor node constituting one sensor row in a touch panel according to the present invention,
6 illustrates an embodiment of a node electrode line connecting a touch sensor node constituting a plurality of sensor lines in a touch panel according to the present invention,
7 shows an embodiment of a wiring electrode line for connecting node electrode lines to each other according to a second embodiment of the touch panel according to the present invention,
FIG. 8 illustrates a configuration in which node electrode lines are connected according to the wiring electrode line configuration according to the second embodiment of FIG. 7,
9 shows another embodiment of a wiring electrode line for connecting node electrode lines to each other as a third embodiment of the touch panel according to the present invention,
10 shows a fourth embodiment of the touch panel according to the present invention,
Fig. 11 shows a configuration for connecting the first node electrode line between adjacent sensor rows in the fourth embodiment of Fig. 10,
12 shows a fifth embodiment of the touch panel according to the present invention,
Fig. 13 shows a configuration for connecting the first node electrode line between adjacent sensor rows in the fifth embodiment of Fig. 12,
FIG. 14 shows an embodiment of a user touch of a touch panel according to the present invention,
FIG. 15 is a flowchart illustrating a touch recognition process of the touch panel according to the present invention,
FIG. 16 shows the process of recognizing the user's touch in FIG. 14,
17 shows an embodiment in which a shielding line is formed on a touch panel according to the present invention,
FIG. 18 shows an operation diagram for the embodiment of FIG. 17,
FIG. 19 shows an embodiment in which a radial touch sensor node according to the present invention is applied,
20 illustrates an exemplary structure of various touch sensor nodes applied to a touch panel according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

First, the terminology used in the present application is used only to describe a specific embodiment, and is not intended to limit the present invention, and the singular expressions may include plural expressions unless the context clearly indicates otherwise. Also, in this application, the terms "comprise", "having", and the like are intended to specify that there are stated features, integers, steps, operations, elements, parts or combinations thereof, But do not preclude the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The present invention relates to a touch sensor node comprising a first configuration for a node electrode line connecting touch sensor nodes on a touch sensor node matrix, a second configuration for a wiring electrode line connecting the node electrode line to a driving circuit, And a third configuration for a node pattern. Hereinafter, the first configuration, the second configuration, and the third configuration will be described with reference to the embodiments in order.

A first configuration according to the present invention is a node electrode line connecting touch sensor nodes on a touch sensor node matrix, wherein a plurality of touch sensor nodes are arranged in a column direction, And each of the touch sensor nodes of the touch sensor node matrix configured to be spaced apart from each other by a predetermined distance.

FIG. 4 illustrates a first embodiment of the configuration of a node electrode line of a touch panel according to the present invention, and the first configuration according to the present invention will be described with reference to FIG. 4 .

As shown in the first embodiment of FIG. 4, a plurality of touch sensor nodes 120a1, 120a2, ... are arranged in a column direction, and the touch sensor nodes 120a1, 120a2, A plurality of sensors 110a, 110b, 110c,... 110n are arranged at predetermined intervals to constitute a touch sensor node matrix.

The two touch sensor nodes 120a1 and 120a2 constituting the sensor array 110a are classified into a pair of touch sensor nodes 120a1 and 120a2 and connected to one electrode line for each pair of touch sensor nodes, In order to recognize the touch of the touch sensor node of the user, two electrode lines must be connected to each touch sensor node. Therefore, in the present invention, the first node electrode line 210 connected to each touch sensor node, And the second node electrode line 250 are connected to each other.

Here, in order to individually recognize the touches of the two touch sensor nodes classified as the touch sensor node pair, the touch sensor node pair to which the first node electrode line 210 is connected is connected to the second node electrode line 250 The touch sensor node pairs are formed to be different from each other.

5 illustrates a node electrode line connecting a touch sensor node constituting one row in a touch panel according to an embodiment of the present invention.

As shown in FIG. 5, the touch sensor nodes 120a1, 120a2, 120a3, 120a4, and 120a5 form one sensor row 110a. In the configuration in which the first node electrode line 210 is connected, Two touch sensors 120a and 120a2 in the touch sensor nodes 120a1, 120a2, 120a3, 120a4 and 120a5 constituting the sensor array 110a are classified into the touch sensor node pair A and the two touch sensor node pairs A A first node electrode line 210a connecting the touch sensor nodes 120a1 and 120a2 to one electrode line is formed. That is, in FIG. 5, the touch sensor nodes 120a1, 120a2, 120a3, 120a4, and 120a5 are sequentially classified in order from the top, and one first node electrode line 210a is connected to each touch sensor node pair A Is shown.

5, the touch sensor nodes 120a1, 120a2, 120a3, 120a4, and 120a5 included in the sensor array 110a are sequentially connected to the second node electrode line 250 from the top, Since the two touch sensor node pairs A are connected to the first node electrode line 210a, the touch sensor node pair A is connected to the first node electrode line 210a, In order to classify the sensor node pairs, a pair of two touch sensor nodes 120a2 are formed, and a second node electrode line 250a is connected to each pair of touch sensor nodes B.

5, the shape of a node electrode line for one sensor line 110a is extended to a touch sensor node matrix including a plurality of sensor lines. In the case of the embodiment of FIG. 5, A first node electrode line may be formed on the left side surface and a second node electrode line may be formed on the right side surface of each sensor node row. Accordingly, the first node electrode line and the second node electrode line are formed between the rows of the sensors. In this case, generally, due to the formation of an electric field according to the current flow of the node electrode line according to the touch of the user, An electric field corresponding to the current flow of the first node electrode line may have a signal influence on the adjacent second node electrode line, so that an erroneous operation may occur. Therefore, in the present invention, the first node electrode line and the second node electrode line are arranged as far as possible in order to minimize the error operation. In this regard, FIG. 5 is a cross- And a node electrode line connecting the touch sensor node.

In FIG. 6, four sensor columns 110a, 110b, 110c, and 110d are shown. Since the basic node electrode line configuration for each sensor column is the same as that of FIG. 5, A detailed description will be omitted.

In FIG. 6, two node electrode lines of the same kind among the first node electrode line and the second node electrode line are formed to connect adjacent sensor lines between two sensor columns. The first sensor line 110a and the second sensor line The second node electrode line 250a corresponding to the first sensor line 110a and the second node electrode line 250b corresponding to the second sensor line 110b are formed between the second sensor lines 110b, A first node electrode line 210b corresponding to the second sensor line 110b and a first node electrode line 210b corresponding to the third sensor line 110c are provided between the second sensor line 110b and the third sensor line 110c 210c are formed.

In this case, since two touch sensor nodes are classified into a pair and connected to the second node electrode line 250a so as to be different from the pair of touch sensor nodes connected to the first node electrode line 210a, The first touch sensor node 120a1 of the first sensor array 110a may not be paired with the touch sensor node of the first sensor array 110a when the second sensor line 110a connects the second node electrode line, The first touch sensor node 120b1 of the column 110b may not be paired with the touch sensor node on the second sensor row 110b. Therefore, since there are touch sensor nodes 120a1 and 120b1 that are not paired on the same sensor row, individual node electrode lines may be formed for each of the touch sensor nodes 120a1 and 120b1, The touch sensor nodes 120a1 and 120b1 that are not paired in the second sensor row 110b and the third sensor row 110c are classified into a pair and extended to one second node electrode line 251 The number of the node electrode lines can be further reduced.

As described above, the same kind of node electrode line is formed between two rows of the touch sensor node, and the first node electrode line and the second node electrode line are alternately formed between the sensor columns, It is possible to minimize the error operation due to the signal influence of the adjacent node electrode line.

In addition, a wiring electrode line for connecting the configuration of the node electrode line according to the first embodiment of the present invention shown in FIGS. 4 to 6 to the driving circuit is formed. In the second structure according to the present invention, A first wiring electrode line connected to an end of the plurality of first node electrode lines and connecting the first node electrode lines to each other and a second wiring electrode line connected to the end of the plurality of second node electrode lines, And a second wiring electrode line connecting the lines to each other.

In this regard, FIG. 7 shows an embodiment of a wiring electrode line connecting the node electrode lines to each other as a second embodiment of the touch panel according to the present invention.

7, the first wiring electrode line 410 is formed so that the first node electrode lines are alternately connected to each other, and the second node electrode lines formed between the sensor rows are connected in the sequential order A second wiring electrode line 450 is formed in the second wiring electrode line 450 so that the second node electrode lines formed between the sensor lines are connected in the same order.

Referring to FIG. 8, a configuration in which each node electrode line is connected to each of the two sensor lines 150 via a wiring electrode line is shown in FIG. 8. In this case, the two sensor lines 110a and 110b A first node electrode line 210 is formed and a second node electrode line 250 is formed between the two sensor lines 110a and 110b along the inner side. The first node electrode line 410 connected to the first sensor row 110a and the first node electrode line 210 connected to each sensor row 110a and 110b are alternately connected to each other, Electrode line 210 and first node electrode lines connected to even-numbered touch sensor node pairs on the second sensor row 110b are all connected and connected to the driving circuit by the first wiring electrode line Y0, and the first sensor row 110a, An even number of times The first node electrode lines 210 connected to the pairs of touch sensor nodes and the first node electrode lines connected to the odd touch sensor node pairs on the second sensor row 210b are all connected to the first connection electrode line Y1, Respectively.

The second connection electrode line 450 connects the second node electrode line 250 formed between the sensor lines in the sequential order. The second connection electrode line 450 connects the second node electrode line 250 in the clockwise direction starting from the last touch sensor node pair of the first sensor line 110a Accordingly, the second node electrode lines 250 connected to the last touch sensor node pair of the second sensor row 110b are sequentially connected to the second wiring electrode lines X0 to X11, respectively.

The first electrode line 410 and the second electrode line 450 are connected to the first node electrode line 210 and the second node electrode line 250, Referring to FIG. 7 again, the first node electrode lines 210 connected to two sensor rows are alternately connected to two first wiring electrode lines to be connected to each other, so that Y0 to Y9 The second wiring electrode line 450 is formed so that the second node electrode lines 250 formed between the two sensor lines are connected in the same order according to the sequential order, And connected to the second wiring electrode lines X0 to X11.

That is, the first node electrode line and the second node electrode line, which are connected to the touch sensor node pairs constituting the touch sensor node matrix through the wiring electrode line 400, are connected to each other according to the order of the wiring electrode lines shown in FIG. And can operate as connected.

The wiring electrode line 400 may be formed on the touch panel module. However, in order to further miniaturize the touch panel module and overcome the space limitation, the wiring electrode line 400 is connected to a PCB or a driving circuit The FPCB may be formed in various ways depending on the circumstances without being limited thereto.

9 is a third embodiment of the touch panel according to the present invention, showing another embodiment of the wiring electrode line for connecting the node electrode lines to each other, wherein the first wiring electrode line for connecting the first node electrode line 410a are the same as those in the embodiment of FIG. 7, and the description thereof will be omitted.

A second wiring electrode line is connected to the end of the second node electrode line formed between the sensor lines. Here, the second node electrode line formed between one adjacent sensor line 150a is sequentially connected from X0 to X11 And the second node electrode lines formed between the adjacent sensor row lines 150b are connected in reverse order from X11 to X0 in the reverse order to the second wiring electrode line 450a.

That is, in the embodiment shown in FIG. 9, for the first two sensor rows 150a, from the last touch sensor node pair of the first sensor row to the last touch sensor node pair of the second sensor row along the clockwise direction, And the second node electrode lines are connected to the second wiring electrode lines X0 to X11 in the sequential order and the second two sensor electrode lines 150b are connected to the second sensor electrode line 150b in the opposite direction to the two sensor rows 150a. Node electrode lines X11 through X0 to the second wiring electrode lines X11 through X0, respectively, the first node electrode line connected to the pairs of touch sensor nodes constituting the touch sensor node matrix through the wiring electrode line 400a, The node electrode lines can be connected to each other according to the order of the wiring electrode lines shown in FIG.

The first configuration of the node electrode line connecting the touch sensor nodes on the touch sensor node matrix according to the present invention and the second configuration of the wiring electrode line connecting the node electrode line to the driving circuit are variously modified Hereinafter, the first configuration and the second configuration will be described in further detail through various embodiments.

FIG. 10 is a cross-sectional view of a touch panel according to a fourth embodiment of the present invention. Referring to FIG.

10, a first node electrode line connected to the first touch sensor node pair of each sensor row among the first node electrode lines formed between the two sensor lines is referred to as a first node electrode line, And is formed as one first node electrode line.

Referring to FIG. 11, when a first node electrode line is formed between adjacent two sensor lines, a first node electrode line between adjacent sensor lines shown in FIG. 10C is connected. The first node electrode line 210b1 connected to the first sensor node pair 120b1 and 120b2 included in the sensor row and the first node electrode line 210c1 connected to the first sensor node pair 120c1 and 120c2 included in the next sensor row The number of the node electrode lines formed between the sensor lines can be reduced by one by forming the first node electrode line as one line.

Referring to FIG. 10 again, the first node electrode lines connected to the respective sensor lines are connected to the first wiring electrode lines 410b in sequential order Here, the first node electrode lines connected to the two sensor rows are connected to the first wiring electrode line 410b in a different order sequentially. At this time, for the first node electrode lines formed between the two sensor columns, The first wiring electrode line 410b is connected so that the first node electrode lines of the same order number are connected to each other according to the order of connection to the columns.

10, the first node electrode line connected to the first sensor row and the second sensor row is connected to the first wiring electrode line 410b, which is different from X0 to X11, and is connected between the sensor row of the second sensor row and the sensor row of the third sensor row The first node electrode line connects the first wiring electrode line 410b extending from X6 to X11 such that the first node electrode line connected to the second sensor line and the first node electrode line connected to the third sensor line are connected in the same order.

12, the configuration of a modified node electrode line and the configuration of a wiring electrode line according to another embodiment of the present invention will be described.

In the embodiment of FIG. 12, the number of node electrode lines is further reduced. Among the first node electrode lines formed between the two sensor lines, the first node connected to the first touch sensor node pair of each sensor row Electrode lines are connected and the first node electrode line connected to the second touch sensor node pair is connected to form one first node electrode line.

Referring to FIG. 13, when a first node electrode line is formed between adjacent two sensor lines, a first node electrode line between neighboring sensor lines shown in FIG. 12D is connected. The first node electrode line 210b1 connected to the first sensor node pair 120b1 and 120b2 included in the sensor row and the first node electrode line 210c1 connected to the first sensor node pair 120c1 and 120c2 included in the next sensor row And are formed as one first node electrode line. The first node electrode lines 210b2 and 210c2 connected to the second sensor node pair 120b3 and 120b4 120c3 and 120c4 are also connected to form a first node electrode line.

At this time, in order to form the first node electrode line connected to the first sensor node pair 120b1, 120b2, 120c1, 120c2 between sensor rows, a multi-layer structure must be formed, The bezel region of the touch module as shown in FIG.

12 is similar to the wiring electrode line of the embodiment of FIG. 10, so that detailed description thereof will be omitted.

Hereinafter, a process of recognizing a user's touch on a specific touch sensor node by applying the touch panel according to the present invention will be described.

The first wiring electrode line and the second wiring electrode line may be selectively applied to Tx and the other Rx according to the operation of the driving circuit, But are not limited to Tx and Rx, respectively.

For convenience of description, the driving operation of the embodiment of FIG. 7 will be described with reference to FIG.

In the embodiment of the driving operation shown in FIG. 14, the first wiring electrode line 410 is applied as Rx and the second wiring electrode line 450 is applied as Tx for convenience of explanation.

The process of recognizing the user's touch on the touch panel according to the present invention when the specific part 500 of the touch panel is touched with the finger of the user as shown in FIG. 14 is described with reference to the touch of the touch panel according to the present invention Referring to the flow chart of the recognition process, signals are sequentially applied to Tx. In FIG. 14, since the second wiring electrode line 450 is set to Tx, the second wiring electrode line 450 sequentially from X0 to X11 A signal is applied to each of the second wiring electrode lines 450 in order. At this time, if a signal is applied to the Tx of each sequence, the second wiring electrode line 450, which is Rx, recognizes that a specific touch sensor node is touched through two reading processes (S30, S40) do.

16 is a process of recognizing the user's touch shown in FIG. 14. First, in a state where a signal is applied to the second wiring electrode line X0 corresponding to Tx # 0 (S20) The first wiring electrode line corresponding to the even-numbered Rx is grounded and the first wiring electrode line corresponding to the odd-numbered Rx is loaded into the input mode (S30), so that the first wiring electrode line corresponding to the odd- Only inputs to the sensor node 510 are performed. Conversely, if the first wiring electrode line corresponding to the odd-numbered Rx is grounded and the first wiring electrode line corresponding to the even-numbered Rx is read as the input mode (S40) as shown in FIG. 16B, The input is performed only to the touch sensor node 530 to which the first wiring electrode line corresponding to the touch sensor node 530 is connected. As described above, one of the Rx is read in the ground state and the other is read in the input mode state. By grounding the first wiring electrode line 410, the specific touch sensor node touched by the user can be recognized more accurately. That is, not only the first wiring electrode line to which the actual signal is inputted due to the touch of the user but also the influence of the signal on the adjacent first wiring electrode line according to the electric field generation is affected. In the present invention, 1 connection electrode lines are grounded, it is possible to prevent the electric field generation caused by the user's touch from being applied to the other first connection electrode line.

This process is repeated in the same manner (S60) for the second wiring electrode line 450 (X1 to X11) corresponding to each of the next Tx # 1 to the last time, and the specific touch sensor node If a user touches (500) in FIG. 14, a signal is applied to the first wiring electrode line X3, and when performing the process of FIGS. 16A and 16B, The first wiring electrode line is grounded and the first wiring electrode line corresponding to the even-numbered Rx is read in the input mode (S40), so that the specific touch sensor node 550 touched by the user can be recognized.

Through the above-described recognition process of the touch panel, it is possible to recognize an accurate user's touch on the touch panel according to the present invention.

In order to minimize the erroneous operation due to the influence of the signal of the adjacent node electrode line, shielding lines for shielding the influence of the signal may be formed more stably. FIG. 17 is a cross- Fig.

As shown in FIG. 17, a first node electrode line 210b connected to one row 110b and a second column electrode 110b connected to the other row 110b and 110c of the touch sensor node, A first node electrode line 210b connected to one column 11b and a first node electrode line 210b connected to the other column electrode 110c are formed. Shielded lines 300 are formed between the shielded lines 210a and 210c so as to shield the signals from each other.

17, the shielding line 300 may be formed as shown in the operation diagram of the embodiment of FIG. 17. Referring to FIG. In the case of FIG. 18 (a) in which the user touches the touch sensor node located in one row 110c, the adjacent electrode line 210c is connected to the adjacent A signal influence to the first node electrode line 210b may be generated and an error may be recognized that the touch sensor node of another column 110b which is not actually touched is touched. When the user touches the touch sensor node located in one row 110c by forming the line 300, even if an electric field is generated due to the current flow of the first node electrode line 210c connected thereto, The shield along a line 300 to flow since the first signal to effect a first node electrode lines (210b) are adjacent so short.

According to the present invention, by forming the node electrode line for each touch sensor node constituting the touch sensor node matrix, an accurate touch can be recognized, and further, a shield line can be formed and the electric field The influence of the signal of the adjacent node electrode line due to the formation of the touch panel can be blocked, thereby further increasing the reliability of the touch panel.

Next, as a third configuration according to the present invention, a sensor node pattern of the touch sensor node will be described with reference to an embodiment. Various known patterns such as a rhombus-shaped node pattern and a snowflake pattern may be applied as the touch sensor node applicable to the touch panel according to the present invention. However, in the present invention, And starts the sensor node pattern.

FIG. 19 illustrates an embodiment in which a radial touch sensor node according to the present invention is applied. In the various embodiments as shown in FIGS. 4 to 12, a radial touch sensor node may be applied as a touch sensor node pattern as shown in FIG. .

20 further illustrates various types of touch sensor nodes that can be applied in the present invention.

FIG. 20A illustrates a first sensor node pattern 125 formed by radially protruding a plurality of branches from a center, a first sensor node pattern 125 formed by protruding radially from a center, And a second sensor node pattern 121 spaced apart from the first sensor node pattern 125 and corresponding to an outer shape of the first sensor node pattern 125 so as to surround an outer periphery of the first sensor node pattern 125, The first sensor node pattern 125 may be connected to the first node electrode line and the second sensor node pattern 121 may be connected to the second node electrode line.

The touch sensor node pattern 120a shown in FIG. 20B includes a plurality of second sensor node patterns 121a and a plurality of second sensor node patterns 121a, And a first sensor node pattern 125a spaced a predetermined distance from the first sensor node pattern 121a and corresponding to a plurality of arrow shapes of the second sensor node pattern 121a.

20 (c), the second sensor node pattern 121b and the second sensor node pattern 121b are spaced apart from the second sensor node pattern 121b by a predetermined distance while being rotated by a predetermined angle in an eddy shape from the outer edge to the center, The touch sensor node pattern 120b may be formed as a first sensor node pattern 125a corresponding to a plurality of eddy shapes of the sensor node pattern 121b.

As described above, the first sensor node pattern and the second sensor pattern node of the one touch sensor node are uniformly dispersed over the entire surface, so that when the user touches the end of the touch sensor node or touches the center, So that accurate touch recognition can be performed irrespective of whether or not the touch is recognized.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments of the present invention are not intended to limit the scope of the present invention but to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

100, 100a: touch panel,
110, 110a, ... 110n: sensor column,
120, 120a1, 120a2, ... 120n1, 120n2, 120n3: touch sensor nodes,
121, 121a and 121b: a first sensor node pattern,
125, 125a, 125b: a second sensor node pattern,
210, 210a: a first node electrode line, 250: a second node electrode line,
300: insulation line,
400: Wiring electrode line,
410: first connection electrode line, 450: second connection electrode line.

Claims (9)

In the touch panel,
A touch sensor node matrix, comprising: a plurality of touch sensor nodes arranged in a column direction to form a sensor array, wherein the plurality of sensor array nodes are arranged at intervals of the sensor array;
A plurality of first node electrode lines, which are sequentially connected to the touch sensor nodes in the sensor array and are connected to the touch sensor node pairs, respectively; And
The touch sensor nodes included in the one sensor row are sequentially classified into two pairs of touch sensor nodes so as to be different from the classification of the touch sensor node pairs connected to the first node electrode line, And a plurality of second node electrode lines connected to the second node electrode line. The method according to claim 1,
The first node electrode line and the second node electrode line are formed between the sensor rows, and the first node electrode line and the second node electrode line are formed in the plurality of sensor columns And are alternately formed between the two electrodes,
And the second node electrode line is connected by classifying the first two touch sensor nodes included in the two subsequent sensor rows into a pair of touch sensor nodes. 3. The method of claim 2,
Wherein the first node electrode lines connected to the two adjacent sensor lines having the first node electrode line formed between the sensor lines are connected to each other and formed as one first node electrode line. The method of claim 3,
One first node electrode line formed by connecting the first first node electrode lines connected to two adjacent sensor lines in which the first node electrode lines are formed between sensor rows is formed along a bezel region of the touch module,
And the second first node electrode line connected to the two sensor lines are connected to each other to form a first node electrode line. 3. The method of claim 2,
A plurality of first wiring electrode lines which are connected to each other so that a plurality of first node electrode lines connected to one sensor line are alternately connected to each other; And
And a plurality of second wiring electrode lines connected to the plurality of second node electrode lines formed between the sensor rows in order,
Wherein the second wiring electrode line is connected such that the second node electrode lines of the same order formed between the sensor lines are connected to each other. 3. The method of claim 2,
A plurality of first wiring electrode lines which are connected to each other so that a plurality of first node electrode lines connected to one sensor line are alternately connected to each other; And
And a plurality of second wiring electrode lines, each of which is connected to the plurality of second node electrode lines formed between adjacent sensor rows in order,
Wherein the second node electrode line is connected such that a second node electrode line of a sequential order formed between one sensor row and a second node electrode line of a reverse order formed between adjacent sensor rows are connected to each other, panel. The method according to claim 3 or 4,
A first wiring electrode line connected to a plurality of first node electrode lines formed outside the adjacent two sensor lines according to a sequential order connected to each sensor row; And
And a plurality of second wiring electrode lines connected to the plurality of second node electrode lines connected to one sensor line so as to be alternately connected to each other. The method according to claim 1,
The touch sensor node includes:
A first sensor node pattern formed by projecting a plurality of branches radially from a center; And
And a second sensor node pattern spaced apart from the first sensor node pattern so as to surround an outer periphery of the first sensor node pattern corresponding to an outer shape of the first sensor node pattern,
Wherein the first sensor node pattern is connected to one of the first node electrode line and the second node electrode line, and the second sensor node pattern is connected to the other one of the first node electrode line and the second node electrode line. The method according to claim 1,
The touch sensor node includes:
A second sensor node pattern having an outer rim and a plurality of arrow shapes extending from the outer rim toward the center; And
And a first sensor node pattern formed inside the outer rim and spaced apart from the second sensor node pattern and corresponding to a plurality of arrow shapes of the second sensor node pattern,
Wherein the first sensor node pattern is connected to one of the first node electrode line and the second node electrode line, and the second sensor node pattern is connected to the other one of the first node electrode line and the second node electrode line.

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