KR20230021815A - Touch screen with improved touch sensitivity deviation and method of improving touch sensitivity deviation - Google Patents

Abstract

The present invention discloses a touchscreen that improves a touch sensitivity deviation due to a difference in a sensor signal line length and a method for improving the touch sensitivity deviation of the touchscreen. According to the touchscreen that improves the touch sensitivity deviation and the method for improving the touch sensitivity deviation according to the present invention, a sensitivity of a touch sensor disposed on the touchscreen can be maintained at the same level without a process of changing the length of the sensor signal line. The touchscreen comprises: at least one first sensor signal line; a first shielding plate; at least one second sensor signal line; and a second shielding plate.

Description

Touch screen with improved touch sensitivity deviation and method for improving touch sensitivity deviation

The present invention relates to a touch screen, and more particularly, to a touch screen capable of improving touch sensitivity deviation due to a difference in sensor signal line length and a method for improving touch sensitivity deviation of the touch screen.

In general, a touch screen panel is formed on a display device such as a liquid crystal display (LCD), a plasma display panel (PDP), an organic light emitting diode (OLED), or an active matrix organic light emitting diode (AMOLED). Or, as being coupled, it is one of the input devices that generate a position signal corresponding to a corresponding position when an object such as a finger or a pen is touched. Touch screen panels are used in a very wide range of fields, such as small portable terminals, industrial terminals, and digital information devices (DIDs), and the fields of use are expanding.

A capacitive touch screen is a device that can determine whether or not a touch has been made based on a change in an electrical signal formed in capacitance generated between a finger on the body or a touch input tool having similar conductivity characteristics and a touch pattern of a touch screen panel.

As shown in FIG. 1A , the touch screen 100-a has a matrix structure in which touch pads on which touch sensors 110-a are formed are arranged in a plurality of columns and rows.

The sensor signal line 120-a connected to each touch sensor is connected to the touch IC 130-a disposed on one side of the touch screen.

In a touch screen having a matrix structure, resistance or capacitance varies according to a distance between a touch sensor and a touch IC, even if sensor signal lines connect the same column or row.

That is, a sensor signal line connected to a touch sensor disposed close to the touch IC 130-a has a shorter length and a lower resistance value than a sensor signal line connected to a touch sensor disposed far from the touch IC 130-a.

In the touch screen shown in FIG. 1A , among the six touch sensors belonging to the same column, the length of the sensor signal line connected to the touch sensor in row 1 is longer than the length of the sensor signal line connected to the touch sensor in row 6

Accordingly, the total capacitance or resistance value generated in the touch sensors disposed in row 1 is greater than the total capacitance or resistance value generated in the touch sensors disposed in row 6.

Similarly, in the touch screen 100-b shown in FIG. 1B, among the four touch sensors 110-b belonging to the same row, the total capacitance or resistance values generated in the touch sensors disposed in columns 1 and 2 are in column 3. and a total capacitance or resistance value generated in the touch sensors arranged in the fourth column.

In this way, the sensor sensitivity of the touch sensor is changed by the difference in the length of the sensor signal line 120-b and, consequently, the difference in resistance value or capacitance.

Methods for improving the variation in sensor sensitivity have been proposed.

FIG. 2A schematically illustrates a structure for compensating for a touch sensitivity deviation of the touch screen of FIG. 1A.

As shown in FIG. 2A , the sensor signal line connected to the touch sensor in row 6 includes an additional compensation section 240-A for compensating for a difference in resistance value or capacitance.

FIG. 2B schematically illustrates a structure for compensating for a touch sensitivity deviation of the touch screen of FIG. 1B.

As shown in FIG. 2B, the sensor signal lines connected to the touch sensors in columns 1 and 2 have an additional compensation section 240-B for compensating for a difference in resistance or capacitance.

However, the compensation sections 240-A and 240-B shown in FIGS. 2A and 2B are designed to reflect the compensation section due to the widening of the compensation signal line and the size of the PCB and COF (Chip On Film). There is a limitation that the area is extremely limited.

Patent Document 1 Registered Patent Publication No. 10-1374312 (2014.06.14) Patent Document 2 Registered Patent Publication No. 10-1609992 (2016.03.31)

The present invention is to solve the problems of the conventional touch screen discussed above, and provides a touch screen and a method for improving touch sensitivity deviation of the touch screen, in which touch sensitivity deviation due to a sensor signal line length difference is improved.

In a touch screen having a plurality of touch sensors arranged in a plurality of rows and columns and a plurality of sensor signal lines connected to the touch sensors according to an embodiment of the present invention,

at least one first sensor signal line of a first length;

a first shielding plate forming a first coupling capacitance with the first sensor signal line when a first voltage is applied;

at least one second sensor signal line of a second length; and

and a second shielding plate forming a second coupling capacitance with the second sensor signal line when a second voltage is applied.

Preferably,

Applying the first voltage determined based on the first length to the first shielding plate and applying the second voltage determined based on the second length to the second shielding plate,

The touch sensitivity of the first touch sensor connected to the first sensor signal line and the touch sensitivity of the second touch sensor connected to the second sensor signal line may be adjusted to the same level.

Preferably,

The first length is shorter than the second length,

It is characterized in that the first voltage is greater than the second voltage.

Preferably,

The first shielding plate is formed on an upper layer or a lower layer of the first sensor signal line,

The second shielding plate may be formed on an upper layer or a lower layer of the second sensor signal line.

Preferably,

The first sensor signal line is a sensor signal line connected to a touch sensor in the same column,

The second sensor signal line is a sensor signal line connected to a touch sensor in a column different from a column of the first sensor signal line,

It is characterized in that the length of the first sensor signal line belonging to the same row is shorter than the length of the second sensor signal line.

Preferably,

A first total capacitance formed in the first touch sensor and a second total capacitance formed in the second touch sensor are adjusted to the same level.

Preferably,

The first total capacitance includes the first coupling capacitance, a first touch capacitance formed in the first touch sensor, and a first parasitic capacitance, and the second total capacitance includes the second coupling capacitance and the second touch capacitance. It is characterized in that it includes a second touch capacitance and a second parasitic capacitance formed in the sensor.

In the touch sensitivity deviation improvement method of a touch screen having a plurality of touch sensors arranged in a plurality of rows and columns and a plurality of sensor signal lines connected to the touch sensors according to another embodiment of the present invention,

Applying a first voltage to a first shielding plate, wherein the first shielding plate forms a first coupling capacitance with at least one first sensor signal line of a first length. applying a first voltage;

Applying a second voltage to a second shielding plate, wherein the second shielding plate forms a second coupling capacitance with at least one second sensor signal line having a second length, the first length being the second length applying the second voltage, which is not equal to;

As the step of adjusting the second voltage, adjusting the touch sensitivity of the first touch sensor connected to the first sensor signal line and the touch sensitivity of the second touch sensor connected to the second sensor signal line to the same level; includes .

Preferably,

The first voltage is determined based on the first length, and the second voltage is determined based on the second length.

Preferably,

The first length is shorter than the second length,

It is characterized in that the first voltage is greater than the second voltage.

Preferably,

The first shielding plate is formed on an upper layer or a lower layer of the first sensor signal line,

The second shielding plate may be formed on an upper layer or a lower layer of the second sensor signal line.

Preferably,

The first sensor signal line is a sensor signal line connected to a touch sensor in the same column,

The second sensor signal line is a sensor signal line connected to a touch sensor in a column different from a column of the first sensor signal line,

It is characterized in that the length of the first sensor signal line belonging to the same row is shorter than the length of the second sensor signal line.

Preferably,

Adjusting the touch sensitivity to the same level,

and adjusting a first total capacitance formed in the first touch sensor and a second total capacitance formed in the second touch sensor to the same level.

Preferably,

The first total capacitance includes the first coupling capacitance, a first touch capacitance formed in the first touch sensor, and a first parasitic capacitance, and the second total capacitance includes the second coupling capacitance and the second touch capacitance. It is characterized in that it includes a second touch capacitance and a second parasitic capacitance formed in the sensor.

According to the touch screen with improved touch sensitivity deviation and the method for improving touch sensitivity deviation according to the present invention, there is an advantage in maintaining the sensitivity of the touch sensor disposed on the touch screen at the same level without a process of changing the length of the sensor signal line.

In addition, the problem of widening the design area due to the separate compensation section in the conventional touch screen can be solved.

According to the touch screen with improved touch sensitivity deviation and the method for improving touch sensitivity deviation according to the present invention, the sensitivity of the touch sensor can be more precisely adjusted (eg, section by section) by adjusting the voltage applied to the shielding plate. there is

1A and 1B are schematic diagrams of a touch screen structure.
2A and 2B are diagrams schematically illustrating a structure for compensating for a touch sensitivity deviation of a touch screen.
3 is a schematic diagram of a touch screen with improved touch sensitivity deviation according to the present invention.
4 is a flowchart according to an embodiment of a method for improving a deviation in touch sensitivity according to the present invention.
5 is a flowchart according to another embodiment of a method for improving a deviation in touch sensitivity according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings and examples.

3 is a schematic diagram of a touch screen with improved touch sensitivity deviation according to the present invention.

A touch screen with improved touch sensitivity deviation and a method for improving touch sensitivity deviation according to the present invention have the advantage of maintaining the sensitivity of the touch sensors disposed on the touch screen at the same level without a separate process for the compensation section of the sensor signal line.

Similar to the touch screen shown in FIG. 1B , the touch screen 300 shown in FIG. 3 has lengths of sensor signal lines connected to touch sensors disposed in columns 1 and 2 among four touch sensors belonging to the same row. It is shorter than the length of the sensor signal line connected to the touch sensor disposed in the 4th column.

As mentioned above, the difference in the length of the sensor signal line eventually leads to a difference in resistance value or capacitance, and makes the sensor sensitivity of the touch sensor different.

Referring to FIG. 3 , among the sensor signal lines connected to the four touch sensors 310 disposed in the fifth row, sensor signal lines 320-1 and 320-2 in the first and second columns are sensor signal lines 320-3 and 320-3 in the third and fourth columns. 320-4) is shorter in length.

As shown in FIG. 3 to solve the deviation of touch sensitivity due to the difference in the length of the sensor signal line, the touch screen of the present invention includes a first shielding plate 340-1 and a second shielding plate 340 -2).

The first shielding plate 340-1 forms a first coupling capacitance with the sensor signal lines 320-1 and 320-2 in the first and/or second columns when a voltage is applied.

The second shielding plate 340-2 forms a second coupling capacitance with the sensor signal lines 320-3 and 320-4 in the third and fourth columns when voltage is applied.

In FIG. 3, the lengths of the sensor signal lines 320-1 and 320-2 in columns 1 and 2 are shorter than the lengths of the sensor signal lines 320-3 and 320-4 in columns 3 and/or 4, but are limited thereto. It is not.

As another example, the lengths of the sensor signal lines 320-1 and 320-4 in columns 1 and 4 may be longer than the lengths of the sensor signal lines 320-2 and 320-3 in columns 2 and 3.

As another example, the length of the sensor signal line 320-1 in column 1 may be shorter than the lengths of the sensor signal lines 320-2, 320-3, and 320-4 in columns 2, 3, and 4.

Adjusting the touch sensitivity of the touch screen of the present invention can be achieved by applying a first voltage to the first shielding plate 340-1 and applying a second voltage to the second shielding plate 340-2.

The first voltage is determined based on the lengths of the sensor signal lines 320-1 and 320-2 in columns 1 and 2, and the second voltage is determined based on the lengths of the sensor signal lines 320-3 and 320-4 in columns 3 and 4. is determined by A first voltage having a shorter length of the sensor signal line is greater than a second voltage of a side having a longer length of the sensor signal line.

Adjusting the touch sensitivity of the touch sensor adjusts the level of the second voltage so that the touch sensitivities of the touch sensors connected to the sensor signal lines in columns 1 and 2 and the touch sensitivities of the touch sensors connected to the sensor signal lines in columns 3 and 4 are at the same level.

The first shielding plate 340-1 may be formed on an upper layer or a lower layer of the sensor signal lines 320-1 and 320-2 in the first and second columns. The second shielding plate 340-2 may be formed on an upper layer or a lower layer of the sensor signal lines 320-3 and 320-4 in the third and fourth columns.

A first total capacitance is formed in the first group of touch sensors (eg, 310-1 and 310-2) by applying a first voltage determined according to the length of the sensor signal line adjacent to the first shielding plate 340-1. do.

By applying a second voltage different from the first voltage to the second shielding plate 340-2, a second total capacitance different from the first total capacitance is applied to the second group of touch sensors (eg, Drung, 310-3 and 310-4). capacitance is formed.

The first total capacitance includes a first coupling capacitance, a first touch capacitance formed in the first group of touch sensors, and a first parasitic capacitance.

The second total capacitance includes a second coupling capacitance, a second touch capacitance formed in the touch sensors of the second group, and a second parasitic capacitance.

The touch screen of the present invention provides a method of improving touch sensitivity deviation without a separate sensor compensation design.

Touch sensors having the same length of sensor signal lines are grouped, and a shielding plate is formed on a layer adjacent to the sensor signal lines connected to the grouped touch sensors.

By applying different voltages to the shielding plates adjacent to the sensor signal lines of different groups, different coupling capacitances can be formed, and sensitivity deviations of the touch sensors can be compensated for using the coupling capacitance deviations.

4 is a flowchart according to an embodiment of a method for improving a deviation in touch sensitivity according to the present invention.

The method for improving the deviation in touch sensitivity of the touch screen according to the present invention will be described using the touch screen shown in FIG. 3 .

A first voltage is applied to the first shielding plate (S410).

The first shielding plate forms a first coupling capacitance with at least one first sensor signal line having a first length.

A second voltage is applied to the second shielding plate (S420).

The second shielding plate forms a second coupling capacitance with at least one second sensor signal line having a second length.

In the example shown in FIG. 3, an embodiment in which the length of the first sensor signal line is shorter than the length of the second sensor signal line has been described, but an arbitrary case in which the first length is not equal to the second length may be included.

The second voltage is adjusted (S430).

By adjusting the second voltage, the touch sensitivity of the first touch sensor connected to the first sensor signal line and the touch sensitivity of the second touch sensor connected to the second sensor signal line are adjusted to the same level.

As described above, the touch sensitivity deviation improvement in the present invention

By applying different voltages to the shielding plates adjacent to the sensor signal lines of different groups, different coupling capacitances can be formed, and sensitivity deviations of the touch sensors can be compensated for using the coupling capacitance deviations.

The touch sensitivity deviation improvement will be described in more detail using Equations 1 and 2.

Here, DB _S is a touch voltage reflecting the touch sensitivity of the touch sensor of the first group of the short sensor signal line,

DB _L is a touch voltage reflecting the touch sensitivity of the touch sensor of the second group of the long sensor signal line;

Vpre is the pre-charge voltage for the touch sensor,

Vdrv is the driving voltage of the touch sensor,

Cp is the capacitance between the touch sensor and the touch sensor,

Cp' is the parasitic capacitance inside the touch IC,

Cd is the capacitance between the touch sensor and the display,

Cdrv is the driving capacitance inside the touch IC,

Cb is the driving capacitance for each sensor channel.

In Equation 1, DB_S represents a touch voltage reflecting the touch sensitivity of the touch sensors of the first group of the short sensor signal lines. DB_S of Equation 1 includes Cp_short (parasitic capacitance according to the length of the sensor signal line).

DB_L represents a touch voltage reflecting the touch sensitivity of the first group touch sensor of the long sensor signal line. DB_L in Equation 1 includes Cp_long.

Cp_short and Cp_long reflect the difference in capacitance according to the difference in the length of the sensor signal line, and even if all other voltage and capacitance values are the same, it can be seen from Equation 1 that the sensitivity deviation of the touch sensor occurs only due to the difference in the length of the sensor signal line. can

Here, DB _S is a touch voltage reflecting the touch sensitivity of the touch sensor of the first group of the short sensor signal line,

DB _L is a touch voltage reflecting the touch sensitivity of the touch sensor of the second group of the long sensor signal line;

Vpre is the pre-charge voltage for the touch sensor,

Vdrv is the driving voltage of the touch sensor,

Cp is the capacitance between the touch sensor and the touch sensor,

Cp' is the parasitic capacitance inside the touch IC,

Cd is the capacitance between the touch sensor and the display,

Cdrv is the driving capacitance inside the touch IC,

Cb is the driving capacitance for each sensor channel,

Vshort is the voltage applied to the shielding plate 340-1 formed on the short sensor signal line side of the Touch IC 330,

Vlong is the voltage applied to the shielding plate 340-2 formed on the side of the long sensor signal line in the Touch IC 330,

Ccouple _short is the coupling capacitance when voltage is applied to the shield plate adjacent to the short sensor signal line,

Ccouple _long is the coupling capacitance when voltage is applied to the shielding plate adjacent to the long sensor signal line.

Equation 2 can form different coupling capacitances by applying different voltages to the shielding plates adjacent to the sensor signal lines of different groups in the present invention, and compensate for the sensitivity deviation of the touch sensor using the deviation of the coupling capacitance. show what is possible

That is, the first voltage Vshort is applied to DB_S of Equation 2 and a first coupling capacitance Couple _short is formed.

A second voltage Vlong is applied to DB_L of Equation 2, and a second coupling capacitance Couple _long is formed.

As can be seen from Equation 2, it can be recognized that a term for compensating the touch sensitivity of the touch sensor has been added by applying different voltages to the shielding plates adjacent to the sensor signal lines of different groups.

5 is a flowchart according to another embodiment of a method for improving a deviation in touch sensitivity according to the present invention.

FIG. 5 This flow chart shows the flow chart shown in FIG. 4 in more detail.

FIG. 5 is characterized by detailing the process of adjusting the touch sensitivity to the same level by adjusting the second voltage in FIG. 4 .

It is divided into at least two groups according to the length of the sensor signal line (S510).

The maximum voltage is applied to the shielding plate of the first group having the shortest sensor signal line among the plurality of groups (S520).

A voltage 0.5V lower than the maximum voltage is applied to the shielding plate of the second group having the long sensor signal line among the plurality of groups (S530).

The touch sensitivities of the first group and the second group are compared (S540).

The comparison of touch sensitivity in S540 is performed by comparing the sensing voltages of the touch sensors of the first group and the second group.

The applied voltage of the second group is gradually lowered until the touch sensitivities of the touch sensors of the first group and the second group reach the same desired level, and the process of comparing the touch sensitivities is repeated (S550).

Each of the embodiments of the present invention described in detail above may be implemented individually or combined with each other to be used interchangeably. The present invention described as described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible without departing from the technical spirit of the present invention. This will be clear to those skilled in the art to which the present invention pertains.

Claims (14)

In a touch screen having a plurality of touch sensors arranged in a plurality of rows and columns and a plurality of sensor signal lines connected to the touch sensors,
at least one first sensor signal line of a first length;
a first shielding plate forming a first coupling capacitance with the first sensor signal line when a first voltage is applied;
at least one second sensor signal line of a second length; and
A touch screen with improved touch sensitivity variation, comprising: a second shielding plate forming a second coupling capacitance with the second sensor signal line when a second voltage is applied. According to claim 1,
Applying the first voltage determined based on the first length to the first shielding plate and applying the second voltage determined based on the second length to the second shielding plate,
A touch screen with improved touch sensitivity deviation, characterized in that the touch sensitivity of the first touch sensor connected to the first sensor signal line and the touch sensitivity of the second touch sensor connected to the second sensor signal line are adjusted to the same level. According to claim 2,
The first length is shorter than the second length,
A touch screen with improved touch sensitivity deviation, characterized in that the first voltage is greater than the second voltage. According to claim 1,
The first shielding plate is formed on an upper layer or a lower layer of the first sensor signal line,
The touch screen with improved touch sensitivity deviation, characterized in that the second shielding plate is formed on an upper layer or a lower layer of the second sensor signal line. According to claim 1,
The first sensor signal line is a sensor signal line connected to a touch sensor in the same column,
The second sensor signal line is a sensor signal line connected to a touch sensor in a column different from a column of the first sensor signal line,
A touch screen with improved touch sensitivity deviation, characterized in that the length of the first sensor signal line belonging to the same row is shorter than that of the second sensor signal line. According to claim 2,
A touch screen with improved touch sensitivity deviation, characterized in that a first total capacitance formed in the first touch sensor and a second total capacitance formed in the second touch sensor are adjusted to the same level. According to claim 6,
The first total capacitance includes the first coupling capacitance, a first touch capacitance formed in the first touch sensor, and a first parasitic capacitance, and the second total capacitance includes the second coupling capacitance and the second touch capacitance. A touch screen with improved touch sensitivity variation, comprising a second touch capacitance and a second parasitic capacitance formed in a sensor. A method for improving touch sensitivity deviation of a touch screen having a plurality of touch sensors arranged in a plurality of rows and columns and a plurality of sensor signal lines connected to the touch sensors,
Applying a first voltage to a first shielding plate, wherein the first shielding plate forms a first coupling capacitance with at least one first sensor signal line of a first length. applying a first voltage;
Applying a second voltage to a second shielding plate, wherein the second shielding plate forms a second coupling capacitance with at least one second sensor signal line having a second length, the first length being the second length applying the second voltage, which is not equal to;
As the step of adjusting the second voltage, adjusting the touch sensitivity of the first touch sensor connected to the first sensor signal line and the touch sensitivity of the second touch sensor connected to the second sensor signal line to the same level; comprising , A method for improving touch sensitivity deviation. According to claim 8,
The first voltage is determined based on the first length, and the second voltage is determined based on the second length, touch sensitivity deviation improvement method. According to claim 8,
The first length is shorter than the second length,
Characterized in that the first voltage is greater than the second voltage, touch sensitivity deviation improvement method. According to claim 8,
The first shielding plate is formed on an upper layer or a lower layer of the first sensor signal line,
The second shielding plate is characterized in that formed on the upper layer or lower layer of the second sensor signal line, touch sensitivity deviation improvement method. According to claim 8,
The first sensor signal line is a sensor signal line connected to a touch sensor in the same column,
The second sensor signal line is a sensor signal line connected to a touch sensor in a column different from a column of the first sensor signal line,
The touch sensitivity deviation improvement method, characterized in that the length of the first sensor signal line belonging to the same row is shorter than the length of the second sensor signal line. According to claim 8,
Adjusting the touch sensitivity to the same level,
and adjusting a first total capacitance formed in the first touch sensor and a second total capacitance formed in the second touch sensor to the same level. According to claim 13,
The first total capacitance includes the first coupling capacitance, a first touch capacitance formed in the first touch sensor, and a first parasitic capacitance, and the second total capacitance includes the second coupling capacitance and the second touch capacitance. A touch sensitivity deviation improvement method comprising a second touch capacitance and a second parasitic capacitance formed in a sensor.

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