KR102274439B1 - Method for detecting a touch input on a virtual bezel and device for the same - Google Patents

Abstract

A touch sensing panel, a touch sensing circuit unit for detecting the intensity of a touch input to each touch sensing node defined in the touch sensing panel, a bezel disposed along an edge of the touch sensing panel and outside of the edge, and the touch sensing panel Discloses a user device including a proximity input sensing unit that determines the presence or absence of a touch input to the bezel based on the intensity of a touch input signal detected by a plurality of touch sensing nodes defined on the edge of the .

Description

Method for detecting a touch input on a virtual bezel and device for the same}

The present invention relates to a technique for detecting a user input to a user device, and includes a technique for detecting a user input to the outside of the edge of a touch panel using a capacitive touch sensing technique.

The conventional smart watch having a circular shape imitates a mechanical rotating bezel installed on the round edge of a traditional wrist watch with a bezel. That is, in the conventional smart watch, a touch panel having a circular sensing area and a ring-shaped mechanical rotating bezel installed on the outside of the touch panel, the bezel being rotatable in a clockwise or counterclockwise direction with respect to the body of the smart watch. may be provided. The bezel is a mechanical component, and the smart watch is configured to detect a rotation angle of the bezel, and may be configured to perform various functions based on the detected rotation angle.

Although there is a problem that the configuration of the smart watch cannot be further simplified mechanically or mechanically due to the conventional mechanical rotating bezel installed in the smart watch, thanks to the user convenience provided by the mechanical rotating bezel, the mechanical rotating bezel is replaced with a smart watch There has been a continuous demand from the market to include it in the

On the other hand, if it is desired to remove the mechanical rotating bezel in response to the market demand, a method of providing, for example, a donut-shaped electrode pattern for capacitive touch sensing at a place where the conventional mechanical rotating bezel is disposed may also be considered. However, when the donut-shaped electrode pattern is provided, it is provided in addition to the circular-shaped electrode pattern basically provided in the smart watch body, and consequently complicates the structure of the smart watch. In addition, since the donut-shaped electrode pattern is disposed at the outermost part of the smart watch, it may be sensitive to external shocks, so it is difficult to guarantee the durability of the donut-shaped electrode pattern.

On the other hand, even on a smart watch or tablet or notebook pad having a non-circular shape, mechanical operation is not possible and is fixed, and a dummy bezel is a bezel that is not equipped with a separate touch sensing circuit pattern for touch sensing. ) can be provided. The dummy bezel does not provide a user input function and may simply be a portion surrounding the outside of the touch panel.

The inventors of the present invention have recognized that it is necessary to provide a technology capable of generating a touch occurrence fact and specific information related thereto in a situation in which a touch occurs on the surface of the dummy bezel. In addition, it was recognized that the provision of a technology capable of reducing power consumption of a portable user device is also required when providing such a new technology.

The technology provided by the present invention can be applied not only to the smart watch, but also to other types of user devices such as tablets or laptops.

In the present invention, in order to solve the above problem, a virtual bezel sensing area is set outside the edge of the touch sensing panel installed in the user device, and the user's touch input to the virtual bezel sensing area is applied to the touch sensing panel. We want to provide technology to recognize using

The reason why the bezel sensing area is referred to as 'virtual' is that an element for sensing a user input is not disposed in the bezel sensing area. The virtual bezel sensing area may be a concept corresponding to the above-described dummy bezel.

1 is a diagram for explaining a proximity phenomenon. Hereinafter, it will be described with reference to FIG. 1 .

In the present invention, a proximity phenomenon using an electric field is used. A phenomenon in which the touch IC recognizes a finger or a conductive material that has reached the surface of the capacitive touch screen within a certain distance (d) is called proximity. The touch IC transmits/receives a signal having greater power to a sensing channel to obtain the proximity phenomenon, and can distinguish the proximity phenomenon by using a touch recognition THD (threshold) and a separate proximity THD. That is, in order to increase SNR and increase sensitivity, the level of the driving energy signal provided to the sensing channel may be increased.

According to one aspect of the present invention, a touch sensing panel (2); a touch sensing circuit unit (4) for detecting the intensity of a touch input to each touch sensing node defined in the touch sensing panel; a bezel (3) disposed on the outside of the edge along the edge of the touch sensing panel; and a proximity input sensing unit that determines whether a touch input exists on the bezel based on the intensity of the touch input signal detected by the plurality of touch sensing nodes 13 defined at the edge of the touch sensing panel. Including, it is possible to provide the user device (1).

In this case, the touch sensing circuit unit is configured to: When the intensity of the touch input signal detected by any one of the plurality of touch sensing nodes defined at the edge of the touch sensing panel is smaller than the first threshold and greater than the second threshold, and determine that a touch input is provided to the bezel. In this case, the first threshold value is greater than the second threshold value.

In this case, the touch sensing circuit unit may include a touch input made by contacting the arbitrary touch sensing node only when the intensity of the touch input signal measured with respect to the arbitrary touch sensing node of the touch sensing panel is greater than the first threshold value. may be adapted to determine what has been provided.

At this time, when it is determined that a touch input is provided to the bezel, the touch sensing circuit unit includes a driving signal provided to the touch sensing panel to detect the intensity of the touch input to each touch sensing node defined in the touch sensing panel. It may be designed to increase energy.

At this time, when it is determined that the bezel is provided with a touch input, the touch sensing circuit unit compares the magnitudes of the intensities of the touch input signals detected by the plurality of touch sensing nodes defined at the edge of the touch sensing panel. Based on , information on a position on the bezel to which a bezel touch input, which is a touch input for the bezel, is provided may be generated.

In this case, a reference point and a reference line passing through the reference point are defined in the user device, and the information on the position on the bezel is the size of the angle between the reference straight line and the straight line connecting the reference point and the position on the bezel. It may contain values related to

In this case, the edge of the touch sensing panel may have a circular shape, the bezel may have a circular shape, and the reference point may be a center point of an area surrounding the bezel.

In this case, the touch sensing panel includes a plurality of electrodes, and the touch sensing circuit unit measures a value of a capacitance formed by each electrode, and based on the measured value, a touch input to each touch sensing node. is configured to detect the strength of , and the bezel may be fixed with respect to the main body of the user device.

In this case, the plurality of electrodes may include: a plurality of first electrodes extending in a first direction; and a plurality of second electrodes extending along a second direction crossing the first direction.

In this case, the plurality of electrodes may include: a plurality of first electrodes concentric and having different radii having a circular shape; and a plurality of second electrodes extending along a second direction crossing the extending direction of the plurality of first electrodes.

At this time, in the normal mode, the user device controls the energy of the driving signal provided to the touch sensing panel to the first level in order to detect the intensity of the touch input for each touch sensing node defined in the touch sensing panel. In the boosting mode, the energy of the driving signal provided to the touch sensing panel is controlled to a second level in order to detect the intensity of the touch input to each touch sensing node defined in the touch sensing panel (second level) 2nd level > first level), and it is determined that the touch input directly contacted on the arbitrary touch sensing node is provided only when the intensity of the touch input to the arbitrary touch sensing node of the touch sensing panel is equal to or greater than the first threshold value may be made to do.

According to the present invention, a virtual bezel sensing area is set outside the edge of the touch sensing panel installed in the user device, and the user's touch input and the location of the touch input to the virtual bezel sensing area are determined using the touch sensing panel. Recognition technology can be provided using

1 is a diagram for explaining a proximity phenomenon.
2A shows the configuration of a user equipment provided according to an embodiment of the present invention.
FIG. 2B shows an example of a method of defining the touch sensing node 10 defined in the touch sensing panel 2 shown in FIG. 2A.
3 is a diagram for explaining a method of generating information about a position on a bezel according to an embodiment of the present invention.
4 shows the shapes of the touch sensing panel and the bezel according to another embodiment of the present invention.
5 is a flowchart illustrating a method of recognizing whether a bezel touch has occurred and calculating information using data of a sensing channel closest to the bezel according to an embodiment of the present invention.
6 is a flowchart illustrating a method of recognizing whether a bezel touch has occurred and calculating information by using the sensing channel data closest to the bezel according to another embodiment of the present invention.
7 is a flowchart illustrating a method of recognizing whether a bezel touch has occurred and calculating information using the sensing channel data closest to the bezel according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be implemented in various other forms. The terminology used in this specification is intended to help the understanding of the embodiments, and is not intended to limit the scope of the present invention. Also, singular forms used hereinafter include plural forms unless the phrases clearly indicate the opposite.

2A shows the configuration of a user equipment provided according to an embodiment of the present invention.

The user device 1 may include a touch screen module. The touch screen module may include a touch sensing panel 2 and a bezel 3 .

The user device 1 according to an embodiment of the present invention includes a touch sensing panel 2 and a touch sensing for detecting the intensity of a touch input to each touch sensing node 10 defined in the touch sensing panel 2 . A circuit part 4, a bezel 3 disposed along the edge of the touch sensing panel 2 and disposed outside the edge, and a plurality of third groups of touch sensing nodes defined at the edge of the touch sensing panel 2 It may include a proximity input sensing unit 5 that determines whether or not a touch input is applied to the bezel 3 based on the intensity of the touch input signal detected by the devices 13 . The proximity input sensing unit may also be referred to as a bezel touch sensing unit.

The touch sensing circuit unit 4 and the proximity input sensing unit 5 may be functional modules included in one chip. The touch sensing circuit unit 4 and the proximity input sensing unit 5 may be regarded as separate concepts from each other, but may also be regarded as a single integrated function module.

The user device 1 may be a device that further includes a processing unit (AP, CPU) that executes an operating system program and an application program, or a display device that does not include the processing unit. When the user device 1 is a display device, the user device 1 may be used in connection with another computing device.

The strength of the touch input signal may be determined by the degree to which the capacitance value formed by the touch sensing node is changed based on the capacitance value when no touch input is made. For example, it may be understood that the greater the change amount of the capacitance of the touch sensing node, the greater the intensity of the touch input signal.

In an embodiment, if there is no change in capacitance of the touch sensing node, the intensity of the touch input signal may be set to 0 (zero).

The touch sensing nodes 10 include a first group of touch sensing nodes 11 disposed at the innermost side, a third group of touch sensing nodes 13 disposed at the outermost edge, and a third group disposed therebetween. It may be divided into two groups of touch sensing nodes 12 .

The area composed of the first group of touch sensing nodes 11 is referred to as a first area, the area composed of the third group of touch sensing nodes 13 is referred to as a third area, and the second group of touch sensing nodes is referred to as a third area. A region composed of the nodes 12 may be referred to as a second region.

The first region, the second region, and the third region may be referred to as an inner region, an intermediate region, and an outer region, respectively.

The plurality of touch sensing nodes 13 may belong to the touch sensing panel 2 .

The bezel 3 may also be referred to as the above-described 'bezel sensing area' or 'dummy bezel' or 'bezel area'.

The bezel 3 may be a region in which an electrode pattern or a sensing channel, which must be provided to execute a capacitive touch input, is not provided.

The touch sensing panel 2 may be referred to as a 'view area', and the visible area may be defined as an area provided with an electrode pattern or sensing channel to be provided in order to execute a capacitive touch input. can

In an embodiment, the touch sensing circuit unit 4 is configured to: When the intensity of a touch input signal detected by an arbitrary touch sensing node 10 of the touch sensing panel 2 is greater than a predetermined first threshold, the It may be configured to determine that a touch input in direct contact with any touch sensing node 10 is provided. And when the intensity of the touch input signal detected by the arbitrary touch sensing node 10 of the touch sensing panel 2 is less than a predetermined first threshold, the touch directly in contact with the arbitrary touch sensing node 10 It may be configured to determine that no input has been provided.

In order to distinguish a touch input in direct contact with the arbitrary touch sensing node 10, that is, a touch input made in direct contact with the surface of the touch input panel 2, from a proximity input or a bezel touch input, 'panel It may also be referred to as 'contact touch input'.

The touch sensing circuit unit capable of detecting the proximity input can detect not only the bezel touch but also the panel contact touch input, but unnecessary power consumption may occur in a situation where detection of the bezel touch is not required, and may not be optimized for The touch sensing circuit unit capable of detecting only the panel contact touch input may have very low reliability even when a proximity input is attempted, but it may maintain a low level of power consumption and may be optimized for the panel contact touch input .

At this time, in one embodiment, the touch sensing circuit unit 4 includes any one of the touch sensing nodes 13 of the plurality of third groups defined at the edge of the touch sensing panel 2 ( When the intensity of the touch input signal detected in 13) is less than the first threshold and greater than a second predetermined threshold, it may be determined that the touch input is provided to the bezel 3 . In this case, the first threshold is greater than the second threshold (second threshold < first threshold).

In this case, the intensity of the touch input signal detected by any one of the touch sensing nodes 13 of the plurality of third groups defined at the edge of the touch sensing panel 2 is the second If it is smaller than the threshold, it may be determined that a touch input directly contacting the one of the touch sensing nodes 13 is not provided, as well as determining that a touch input is not provided to the bezel 3 as well. have.

At this time, in one embodiment, the touch sensing circuit unit 4 includes the plurality of third groups of touch sensing nodes defined at the edge among the touch sensing nodes 10 belonging to the touch sensing panel 2 . When the intensity of the touch input signal detected by any one touch sensing node 11 or 12 arbitrarily selected from the set of nodes 11 + and 12 excluding 13) is less than the first threshold value, Even if the intensity is greater than the second threshold, it may not necessarily be determined that a touch input is provided to the bezel 3 .

In an embodiment of the present invention, the touch sensing circuit unit 4 detects each touch sensing node 10 defined in the touch sensing panel 2 when it is determined that a touch input is provided to the bezel 3 . In order to detect the strength of one touch input signal, the energy of the driving signal provided to the touch sensing panel 2 may be increased. When the energy of the driving signal is increased, it can be evaluated that the input is made not only when direct contact is made on the touch sensing panel, but also when input is attempted while being spaced apart within a predetermined distance from the surface of the touch sensing panel. is provided That is, a proximity touch input or, in other words, a hovering touch input is possible.

Even when a finger comes into contact with the bezel 3 proposed in the present invention, it can be seen that an input is attempted while being spaced apart within a predetermined distance from the surface of the touch sensing panel 2 . Therefore, the technical basis for determining that a touch input has been made on the bezel 3 is sufficient.

In one embodiment of the present invention, when it is determined that the touch input is provided to the bezel 3 , the touch sensing circuit unit 4 includes the plurality of third groups defined at the edge of the touch sensing panel 2 . Based on the result of comparing the magnitudes of the intensities of the touch input signals detected by the touch sensing nodes 13, the position on the bezel 3 to which the bezel touch input, which is the touch input to the bezel 3, is provided. It may be configured to generate information.

For example, one touch sensing node having the largest value among the magnitudes of the intensities of the touch input signals detected by the plurality of third groups of touch sensing nodes 13 defined at the edge of the touch sensing panel 2 . (13) is determined, and the closest part of the determined one touch sensing node 13 among the bezel 3 may be determined as the position where the bezel touch input is made.

Based on the information on the touch input position on the bezel 3, the bezel touch event type, for example, a bezel touch-down event, a bezel touch-up event, and a bezel A touch-mood event (Bezel Touch Move Event), a bezel touch movement distance, and a bezel touch movement direction may be classified.

FIG. 2B shows an example of a method of defining the touch sensing node 10 defined in the touch sensing panel 2 shown in FIG. 2A.

As shown in (a) of FIG. 2B , a group of electrodes extending in the horizontal direction are disposed on the first layer, and a group of electrodes extending in the vertical direction are disposed on the second layer, insulated between the first layer and the second layer By arranging the layers, it is possible to provide electrodes having an overlapping shape as shown in (b) of FIG. 2B .

Now, each of the regions of the electrodes crossing each other in (b) of FIG. 2B can be conceptually defined as one touch sensing node as shown in (c) of FIG. 2B.

Alternatively, the shape of each electrode is not long in one direction, but a small square or rectangular shape close to a square as shown in (d) of FIG. 2B is provided, and a method of arranging them in one first layer may be selected. In addition, each electrode may be regarded as each of the above-described touch sensing nodes. In this case, the electrode provided as shown in (d) of FIG. 2B may detect whether a touch is input using a so-called self-capacitance type capacitive touch sensing technology. Examples of self-capacitance touch sensing technology and electrode arrangement are disclosed in various documents such as, for example, Korean Patent Application Nos. KR10201007298 and KR1020140086784, but are not limited thereto.

3 is a diagram for explaining a method of generating information about a position of a touch input on a bezel according to an embodiment of the present invention.

In the touch sensing circuit unit 4 and/or the proximity input sensing unit 5 of the user device 1, a coordinate system adopted for distinguishing touch input positions on the surface of the touch sensing panel 2 from each other may be defined. . In addition, a reference point 21 that is the origin of the coordinate system and a reference line 22 passing through the reference point 21 may be defined in the touch sensing circuit unit 4 and/or the proximity input sensing unit 5 . The reference point 21 may be, for example, located inside the edge boundary of the touch sensing panel 2 . And, for example, the reference line 22 may be a predefined straight line passing through the reference point 21 . The coordinate system may be a Cartesian coordinate system or a polar coordinate system.

The information on the first position 31 , which is the position of the touch input made on the bezel 3 , is a first straight line that is a straight line connecting the reference point 21 and the first position 31 on the bezel 3 . (32) and the reference line 22 may include a value related to the size of the angle (θ°) between the line (22). That is, the information about the first position 31 may be provided in a form including only the angle between the polar coordinates (θ°).

Alternatively, the information about the first position 31 , which is the position of the touch input made on the bezel 3 , may include the Cartesian coordinates (x,y) of the first position 31 . At this time, the rectangular coordinates (x, y) of the first position 31 on the bezel 3 are not included in the range of the rectangular coordinate area limited to the edge of the touch sensing panel 2 and the range inside it. .

4 shows the shapes of the touch sensing panel and the bezel according to another embodiment of the present invention.

In the embodiment shown in FIG. 4 , the edge of the touch sensing panel 2 may be circular, the bezel 3 may have a donut shape, and the reference point 21 may be a center point of an area surrounded by the bezel 3 . .

In one embodiment of the present invention. The touch sensing panel 2 includes a plurality of electrodes, and the touch sensing circuit unit 4 measures a capacitance value formed by each electrode formed on the touch sensing panel 2, and the measured value It may be configured to detect the intensity of the touch input to each of the touch sensing nodes based on the .

The point that the touch sensing nodes defined in the rectangular touch sensing panel 2 shown in FIG. 3 may have a matrix shape in which rows and columns are orthogonal to each other is exemplified with reference to FIG. 2A .

In comparison, the touch sensing nodes defined in the circular touch sensing panel 2 shown in FIG. 4 may also have a matrix shape in which rows and columns are orthogonal to each other. Alternatively, it can be understood that the touch sensing nodes defined in the touch sensing panel 2 of the circular shape shown in FIG. 4 may be defined by being disposed along the circumference of a plurality of concentric circles.

Examples of the configuration of the touch sensing circuit unit 4 are exemplified in Korean Patent Application Nos. KR1020100095041, KR1020140073021, and KR1020150079768, but are not limited thereto.

The bezel 2 may be fixed to the main body of the user device 1 . Also, the bezel 2 may not include a component that enables mechanical rotation of the user device 1 with respect to the main body. Also, the bezel 2 may not include an electrode that enables capacitive touch sensing.

In the embodiment shown in FIG. 4 , the plurality of electrodes may include a plurality of first electrodes extending in a first direction; and a plurality of second electrodes extending along a second direction crossing the first direction. For example, the plurality of electrodes is exemplified in Patent Application No. KR1020100095041, but is not limited thereto.

Alternatively, in the embodiment shown in FIG. 4, the plurality of electrodes may include: a plurality of first electrodes having concentricity and different radii having a circular shape; and a plurality of second electrodes extending along a second direction crossing the extending direction of the plurality of first electrodes.

5 is a flowchart illustrating a method of recognizing whether a bezel touch has occurred and calculating information using data of a sensing channel closest to the bezel according to an embodiment of the present invention.

In step S10 , the touch sensing circuit unit 4 dynamically controls the flow of the driving current flowing through the plurality of electrodes included in the touch sensing panel 2 to provide a plurality of defined on the touch sensing panel 2 . It is possible to detect the magnitude of the capacitive component associated with the sensing nodes or sensing channels.

Each of the sensing nodes may mean an intersection area of any two electrodes that cross each other among the plurality of electrodes included in the touch sensing panel 2 . Each of the sensing channels may mean each of the sensing nodes. Alternatively, each of the sensing channels may mean each electrode included in the touch sensing panel 2 .

In order to dynamically control the flow of the driving current flowing through the plurality of electrodes, a normal mode and a boost mode may be provided in an embodiment of the present invention. In this case, the boost mode may mean a mode in which the power of the dynamically controlled driving current is increased compared to the normal mode.

In a preferred embodiment, in step S10, the flow of the driving current flowing through the plurality of electrodes in the boots mode may be dynamically controlled.

Alternatively, in another embodiment, in step S10, the flow of the driving current flowing through the plurality of electrodes in the normal mode may be dynamically controlled.

Even when the user device 1 is operated in any of the boost mode and the normal mode, the intensity of the touch input signal may be converted based on the same reference. That is, although the level of the driving current flowing through the electrodes may vary depending on which mode of the boost mode and the normal mode is operated, the capacitance formed or changed in a specific touch sensing node by the same level of touch input. This is because the value does not vary depending on the mode. And this is because the intensity of the touch input signal can be ultimately determined based on the amount of change in the capacitance of the touch sensing node.

However, in the normal mode, if the power supplied through the dynamically controlled driving current is not sufficient, it may be difficult to detect a reliable proximity touch input using the proximity phenomenon in the normal mode, and only the touch sensing panel Only a touch input in direct contact can be reliably sensed.

5 is for explaining a method for detecting whether a touch input has been made on the bezel 3, that is, for explaining a method for detecting whether a proxy kitty input has occurred. It is assumed that operation is performed in the boost mode rather than the mode.

However, as in the conventional embodiment, depending on the embodiment, the user device 1 does not separately provide the normal mode and the boost mode, but may always operate only in a mode that provides a sufficiently large power corresponding to the boost mode. There will be.

In step S20, the proximity input sensing unit 5 measures all the touch input signals detected by the touch sensing nodes 13 of the third group, and selects the touch sensing node having the strongest touch input signal among them. can decide Hereinafter, the touch sensing node having the strongest touch input signal may be referred to as a 'third touch sensing node 131'.

In step S21 , the proximity input detection unit 5 determines whether the intensity of the touch input signal of the third touch detection node 131 is between a second predetermined threshold value and a predetermined first threshold value. can do.

In this case, the first threshold value is greater than the second threshold value. In addition, the first threshold value may be a reference value for determining whether a touch is made by a finger or the like on the touch sensing panel 2 .

For example, if the intensity of the touch input signal detected by the third touch sensing node 131 is greater than the first threshold, it may be considered that a touch input in contact with the surface of the third touch sensing node 131 exists. .

And if the intensity of the touch input signal detected by the third touch sensing node 131 is smaller than the first threshold and greater than the second threshold, there is no touch input in contact with the surface of the third touch sensing node 131 . However, it may be determined that there is a possibility that a touch input has been made in the bezel portion near the third touch sensing node 131 .

If the intensity of the touch input signal detected by the third touch sensing node 131 is less than the second threshold, there is no touch input in contact with the surface of the third touch sensing node 131 and , it may be determined that there is no possibility that a touch input has been made to the bezel portion near the third touch sensing node 131 .

If it is determined that the intensity of the touch input signal of the third touch sensing node 131 is between the second predetermined threshold and the first predetermined threshold, the process may proceed to step S22 .

In step S22 , the proximity input detection unit 5 determines that the intensity of the touch input signal detected by the other surrounding touch sensing nodes 10 existing within the predetermined area including the third touch sensing node 131 is determined. In all cases, it may be determined whether or not the intensity of the touch input signal of the third touch sensing node 131 is smaller than that of the touch input signal.

In particular, the intensity of the touch input signal detected by the touch sensing nodes 12 of the second group existing within the predetermined area including the third touch sensing node 131 is the intensity of the third touch sensing node 131 . It may be determined whether or not the intensity of the touch input signal is smaller than the intensity.

If the strengths of the touch input signals detected by the neighboring touch sensing nodes 10 are all smaller than the strengths of the touch input signals of the third touch sensing node 131 , the touch input of the third touch sensing node 131 . It can be appreciated that it can be determined that the generation of the signal is caused by a touch to the bezel 3 .

On the other hand, if the intensity of the touch input signal detected by any one of the peripheral touch sensing nodes 10 is greater than the intensity of the touch input signal of the third touch sensing node 131, the third touch sensing node ( 131) is not generated by a touch on the bezel 3, but directly touches the surface of another touch sensing node inside the third touch sensing node 131 of the touch sensing panel 2 It can be understood that it is caused by a touch input generated by a touch.

In step S23 , the intensity of the touch input signal detected by the other neighboring touch sensing nodes 10 existing in the predetermined area including the third touch sensing node 131 is all measured by the third touch sensing node 131 . ), when it is determined that the intensity of the touch input signal is smaller than the intensity of the touch input signal, the proximity input sensing unit 5 may determine that the touch input has occurred outside the touch sensing panel 2 (that is, the proximity input has occurred). . In this case, the outside of the touch sensing panel 2 may be regarded as a point of the bezel 3 .

When it is determined that a touch input has occurred on the bezel 3 , there is a possibility that a touch input will continue to occur in other positions of the bezel 3 . At this time, in order to better detect the touch input generated on the bezel 3, if the user device 1 operates in the normal mode in steps S10 to S23, after step S23, the user device 1 ) can be switched from the normal mode to the boost mode. However, in a preferred embodiment, the boost mode may be operated in steps S10 to S23.

In step S24, the proximity input sensing unit 5 is configured to be a second angle between the first straight line 32 connecting the third touch sensing node 131 and the reference point 21 and the reference straight line 22. The angle between 1 can be calculated (θ°).

The first angle (θ°) may be regarded as a value indicating a position of a touch input made on the bezel.

In step S25 , the proximity input sensing unit 5 may transmit the first intervening angle θ° to another IC together with a report signal indicating that the bezel touch has been made. The reason for doing this is that even on the surface of the bezel 3, since a certain area exists in the bezel 3 having a donut shape or a ring shape of any shape, (x, y) coordinates or polar coordinates according to the Cartesian coordinates (r, θ°) can be defined, but among them, for the bezel touch input, it is because there are enough applications to consider only θ° as an input parameter.

The other IC may be included in the user device 1 . Alternatively, the other IC may be provided to another computing device provided separately from the user device 1 .

However, in a modified embodiment, the proximity input sensing unit 5 may provide the other IC with information about the first radius to be provided according to the polar coordinate system together with the first angle θ°. . In this case, the touch input coordinates indicated by the combination of the first radius and the first angle (θ°) may exist outside the touch input panel 2 .

In another modified embodiment, the proximity input sensing unit 5 may convert a position according to a combination of the first radius and the first angle (θ°) into Cartesian coordinates and provide it to the other IC.

6 is a flowchart illustrating a method of recognizing whether a bezel touch has occurred and calculating information by using the sensing channel data closest to the bezel according to another embodiment of the present invention.

In step S10 , the touch sensing circuit unit 4 dynamically controls the flow of the driving current flowing through the plurality of electrodes included in the touch sensing panel 2 to provide a plurality of defined on the touch sensing panel 2 . It is possible to detect the magnitude of the capacitive component associated with the sensing nodes or sensing channels.

In step S30, the proximity input sensing unit 5 is a touch sensing node having a value between a second predetermined threshold value and a predetermined first threshold value, in which the intensity of the touch input signal is a touch of the third group. One third touch sensing node 131 belonging to the sensing nodes 13 may be selected.

In this case, the first threshold value is greater than the second threshold value. In addition, the first threshold value may be a reference value for determining whether a touch is made by a finger or the like on the touch sensing panel 2 .

In step S32 , the proximity input sensing unit 5 determines that the intensity of the touch input signal detected by the other neighboring touch sensing nodes 10 existing in the predetermined area including the third touch sensing node 131 is In all cases, it may be determined whether or not the intensity of the touch input signal of the third touch sensing node 131 is smaller than that of the touch input signal.

In particular, in the second group of touch sensing nodes 12 existing in the predetermined area including the third touch sensing node 131 and the third group of touch sensing nodes 13 present in the predetermined area It may be determined whether all the detected strengths of the touch input signals are less than the strengths of the touch input signals of the third touch sensing node 131 .

In step S33 , the intensity of the touch input signal detected by the other neighboring touch sensing nodes 10 existing in the predetermined area including the third touch sensing node 131 is all the same as that of the third touch sensing node 131 . ), when it is determined that the intensity of the touch input signal is smaller than the intensity of the touch input signal, the proximity input sensing unit 5 may determine that the touch input has occurred outside the touch sensing panel 2 . In this case, the outside of the touch sensing panel 2 may be regarded as a point of the bezel 3 .

In step S34 , the proximity input detection unit 5 generates a second angle between the first straight line 32 connecting the third touch sensing node 131 and the reference point 21 and the reference straight line 22 . The angle between 1 can be calculated (θ°).

In step S35 , the proximity input sensing unit 5 may transmit the first intervening angle θ° to another IC together with a report signal indicating that the bezel touch has been made.

7 is a flowchart illustrating a method of recognizing whether a bezel touch has occurred and calculating information using the sensing channel data closest to the bezel according to another embodiment of the present invention.

In step S41, more signals may be transmitted/received so that the proximity phenomenon occurs in the visible region. That is, it is possible to control the operation of the user device to operate in the boost mode described above.

In step S42 , it may be determined whether a position at which a touch input is sensed among the touch sensing panel 2 exists outside a predetermined area.

If it exists outside the predetermined area, the process may proceed to step S43, and if it does not exist outside the predetermined area, it may proceed to step S45.

In step S43 , the user device 1 may calculate the maximum value K among data of the gamut channels closest to the area of the bezel 3 of the touch sensing panel 2 .

For example, as shown in step S20 of FIG. 5 , by measuring the touch input signal detected by the touch sensing nodes 13 of the third group, the third touch sensing node having the strongest touch input signal ( 131) can be determined. In this case, the intensity of the touch input signal of the third touch sensing node 131 may be the maximum value (K).

In step S44, it may be determined whether the maximum value K is greater than a predetermined value A and less than a predetermined value B.

A and B may be the second threshold value and the first threshold value described in step S21 of FIG. 5 , respectively.

If the maximum value K is greater than the predetermined value A and less than the predetermined value B, the process proceeds to step S46, otherwise the process may be terminated.

In step S46 , it is recognized that the bezel 3 has been touched, and information about the bezel touch input may be generated using the sensing channel data closest to the bezel 3 .

In step S45, since it is determined that the 2D coordinates exist in the predetermined area in step S21, it is determined that the bezel touch has not occurred and the process can be ended.

By using the above-described embodiments of the present invention, those skilled in the art will be able to easily implement various changes and modifications within the scope without departing from the essential characteristics of the present invention. The content of each claim in the claims may be combined with other claims without reference within the scope that can be understood through this specification.

Claims (14)

touch sensing panel (2);
a touch sensing circuit unit (4) for detecting the intensity of a touch input to each touch sensing node defined in the touch sensing panel;
a bezel (3) disposed outside the touch sensing panel, the bezel (3) disposed along an edge of the touch sensing panel and disposed outside the edge; and
a proximity input sensing unit that determines whether a touch input exists on the bezel based on the intensity of the touch input signal detected by the plurality of touch sensing nodes 13 defined at the edge of the touch sensing panel;
containing,
user device. According to claim 1,
The touch sensing circuit unit,
When the intensity of the touch input signal detected by any one of the plurality of touch sensing nodes defined at the edge of the touch sensing panel is less than the first threshold and greater than the second threshold, it is assumed that the touch input is provided to the bezel. to determine (first threshold > second threshold),
user device. 3. The method of claim 2,
The touch sensing circuit unit,
determine that a touch input made in contact with the arbitrary touch sensing node is provided only when the intensity of a touch input signal measured with respect to the arbitrary touch sensing node of the touch sensing panel is greater than the first threshold value;
user device. 3. The method of claim 2,
The touch sensing circuit unit,
When it is determined that a touch input is provided to the bezel, the energy of the driving signal provided to the touch sensing panel is increased in order to detect the intensity of the touch input for each touch sensing node defined in the touch sensing panel,
user device. 3. The method of claim 2,
The touch sensing circuit unit,
When it is determined that a touch input is provided to the bezel, based on a result of comparing the magnitudes of the intensities of the touch input signals detected by the plurality of touch sensing nodes defined at the edge of the touch sensing panel with each other, bezel, which is a touch input, configured to generate information about a position on the bezel to which a touch input is provided;
user device. 6. The method of claim 5,
A reference point and a reference line passing through the reference point are defined in the user device,
The information on the position on the bezel includes a value relating to the magnitude of the angle between the reference line and the straight line connecting the reference point and the position on the bezel,
user device. 7. The method of claim 6,
The edge of the touch sensing panel is circular, the bezel is circular,
The reference point is the center point of the area surrounded by the bezel,
user device. According to claim 1,
The touch sensing panel includes a plurality of electrodes,
The touch sensing circuit unit is configured to measure the value of the capacitance formed by each electrode, and detect the intensity of the touch input to each touch sensing node based on the measured value,
The bezel is fixed to the body of the user device,
user device. 9. The method of claim 8,
The plurality of electrodes,
a plurality of first electrodes extending in a first direction; and
a plurality of second electrodes extending along a second direction crossing the first direction
comprising,
user device. 9. The method of claim 8,
The plurality of electrodes,
a plurality of first electrodes having different radii having concentricity and circular shape; and
a plurality of second electrodes extending along a second direction crossing the extending direction of the plurality of first electrodes
comprising,
user device. According to claim 1,
The touch sensing circuit unit,
In the normal mode, the energy of the driving signal provided to the touch sensing panel is controlled to a first level in order to detect the intensity of a touch input to each touch sensing node defined in the touch sensing panel,
In the boosting mode, the energy of the driving signal provided to the touch sensing panel is controlled to a second level in order to detect the intensity of a touch input to each touch sensing node defined in the touch sensing panel (second level> 1st level), and
determine that the touch input directly contacted on the arbitrary touch sensing node is provided only when the intensity of the touch input to the arbitrary touch sensing node of the touch sensing panel is equal to or greater than a first threshold value;
user device. The user device 1 controls the flow of the driving current flowing through the plurality of electrodes included in the touch sensing panel 2, and is formed in each of the plurality of sensing nodes defined along the edge of the touch sensing panel. Determining the third touch sensing node 131, which is the touch sensing node having the greatest intensity of the touch input signal among them by detecting the size of the capacitive component
When the user device determines that the intensity of the touch input signal detected with respect to the third touch sensing node is between a second predetermined threshold value and a predetermined first threshold value, the third touch sensing node is included. Determining whether the intensity of the touch input signal detected by the other neighboring touch sensing nodes 10 existing in the predetermined area is less than the intensity of the touch input signal of the third touch sensing node (the first threshold) value is greater than the second threshold value); and
If the strength of the touch input signal detected by the user device from the surrounding touch sensing nodes is all lower than the strength of the touch input signal of the third touch sensing node, the bezel 3 disposed outside the touch sensing panel determining that a touch input has occurred;
includes,
The bezel is characterized in that it is disposed outside the touch sensing panel,
A method of detecting whether a touch is input to the bezel. 13. The method of claim 12,
Information on a reference point 21 and a reference straight line 22 passing through the reference point is defined in the touch sensing panel,
The method is
calculating a first angle (θ°), which is an angle between the first straight line (32) connecting the third touch sensing node and the reference point, and the reference straight line; and
transmitting the information on the first angle to another IC provided inside or outside the user equipment;
further comprising,
A method of detecting whether a touch is input to the bezel. The user device 1 controls the flow of a driving current flowing through the plurality of electrodes included in the touch sensing panel 2, and is formed in each of the plurality of sensing nodes defined along the edge of the touch sensing panel. detecting the magnitude of the capacitive component, and selecting a third touch sensing node 131 having a value between a second predetermined threshold value and a predetermined first threshold value, among which the strength of the touch input signal (the above) the first threshold is greater than the second threshold);
The intensity of the touch input signal detected by the user device from the other surrounding touch sensing nodes 10 existing in the predetermined area including the third touch sensing node is the same as that of the touch input signal of the third touch sensing node. determining whether the intensity is less than the intensity; and
When the user device determines that the intensity of the touch input signal detected by the surrounding touch sensing nodes is less than the intensity of the touch input signal of the third touch sensing node, the touch input is generated outside the touch sensing panel determining that;
containing,
A method of detecting whether a touch is input to the bezel.

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