KR100924783B1 - Touch recognition method for use at multi-touch screen in resistive type - Google Patents

Abstract

PURPOSE: A touch recognition method of resistive film type multi-touch screen is provided to prevent touch decision error by filtering virtual touch coordinate through location range verification. CONSTITUTION: A sensing mode is set up which is capable of reading X axis data. If a touch is made, clock is supplied to sense X axis data, X axis cell reading is performed. It is converted to Y axis sensing mode which is capable of reading Y axis data. The Y axis cell reading is performed along the X-axis cells by the supply of clock. The coordinates of the touch point is read through the X axis electrode and Y axis electrode. It is determined whether data of the read-out touch point is in the location or not. If the coordinates are within the location range, the coordinates is confirmed as normal and stored.

Description

Touch recognition method for use at multi-touch screen in resistive type

The present invention relates to a touch recognition method of a resistive multi-touch screen, and more particularly, to a touch recognition method for enabling multi-touch recognition.

1 is a view for explaining a conventional resistive touch screen. As shown in FIG. 1, in the conventional resistive touch screen, the X-axis resistive film (X) and the Y-axis resistive film (Y) overlap each other by a predetermined distance, and both ends of the X-axis resistive film (X) Axis electrodes X +, X- are formed, and Y-axis electrodes Y +, Y- are formed at both ends of the Y-axis resistive film Y. When the point T is touched, the X-axis resistive film X and the Y-axis resistive film Y are in contact with each other, and the voltage read through the X-axis electrodes X + and X- and the Y-axis electrodes Y + and Y- Find XY touch coordinate through.

[X coordinate value]

When Vcc is applied to the X-axis electrodes X + and X- and the voltage is read through the Y-axis electrodes Y + and Y-, the voltage represents the X coordinate.

Vx = Vcc * RX1 / (RX1 + RX2)

[Y coordinate value]

After reading the X coordinate, the X-axis electrodes X + and X- are floated, Vcc is applied to both ends of the Y-axis electrodes Y + and Y-, and the X-axis electrodes X + and X- Reading the voltage, this voltage represents the Y coordinate.

Vy = Vcc * RY1 / (RY1 + RY2)

The conventional resistive touch screen can recognize only one touch coordinate at a time, and when two points are touched, an error occurs due to an unexpected coordinate value due to the formation of a series-parallel sheet resistance between the two points.

Accordingly, an object of the present invention is to provide a touch recognition method of a resistive multi-touch screen capable of multi-touch recognition in order to solve the above problems.

In order to achieve the above object, the present invention overlaps a plurality of X-axis cells partitioned horizontally at regular intervals and a plurality of Y-axis cells partitioned vertically at regular intervals so that touch cells are arranged in a matrix form. Resistive film type multi-touch screens in which X and Y axis electrodes are formed independently at both ends of each of the X and Y axis cells, and the position range of the X and Y axis cells is preset. As for the touch recognition method of,

A first step of waiting in a sensing mode in which the X-axis data can be read;

A second step of supplying a clock to sense X-axis data and reading an X-axis cell when a touch is made;

A third step of switching to a Y-axis sensing mode in which Y-axis data can be read;

A fourth step of supplying a clock to read Y-axis cells for each of the X-axis cells;

A fifth step of reading coordinates of the touch point through the X-axis electrode and the Y-axis electrode;

A sixth step of checking whether the data of the touch point read in the fifth step is in place by switching back to the X-axis sensing mode and the Y-axis sensing mode;

If it is confirmed in step 6 that the data of the touch point is in place, it is determined whether the coordinate value read in step 5 is included in the position range of the touch cell read in step 4 and the coordinate value. And a seventh step of determining and storing a normal coordinate value if it is within the location range, and discarding it by determining that it is a virtual coordinate value if it is outside the location range.

When another touch point other than the touch point exists, if the other touch point is on the same X-axis cell as the touch point, the step after the fifth step may be performed with respect to the other touch point. If the other touch point is on an X-axis cell different from the touch point, it is preferable to perform the step after the fourth step with respect to the other touch point.

In the reading of the cell in the second step or the fourth step, in the case of adjacent cells, it is preferable that the cell is processed as a bundle without processing the sequence with each cell.

In the present invention, the X axis and the Y axis mean an orthogonal coordinate, and the touch recognition process is not limited to the X axis first and the Y axis later. For example, in the touch recognition method, a first step of waiting in a sensing mode for reading Y-axis data; A second step of reading a Y-axis cell by sensing a Y-axis data by supplying a clock when a touch is made; A third step of switching to an X-axis sensing mode in which the X-axis data can be read; The order of the X-axis and the Y-axis may be changed as in the fourth step of supplying a clock to read the X-axis cell for each Y-axis cell.

According to the present invention, multi-touch recognition is possible, and virtual touch coordinates can be filtered through the position range checking step, thereby eliminating a touch determination error. The power consumption is reduced because the clock is supplied until the touch is made in the sensing mode and the touch is made.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. The following examples are only presented to understand the content of the present invention, and those skilled in the art will be capable of many modifications within the technical spirit of the present invention. Therefore, the scope of the present invention should not be construed as limited to these embodiments.

2 is a block diagram of a multi-touch screen for explaining a multi-touch recognition method of a resistive multi-touch screen according to the present invention. As shown in FIG. 2, the multi-touch screen to which the present invention is applied includes a plurality of X-axis cells X1 and X2 by partitioning the X-axis resistive film X of the conventional touch screen as shown in FIG. 1 at regular intervals horizontally. , X3, .. Xn are formed, and the Y-axis resistive film Y is divided at regular intervals vertically so that a plurality of Y-axis cells Y1, Y2, Y3, .., Yn are formed. Therefore, square touch cells are arranged in a matrix form. X-axis electrodes (Xn +, Xn-) and Y-axis electrodes (Yn +) at both ends of each of the X-axis cells (X1, X2, X3, ..Xn) and Y-axis cells (Y1, Y2, Y3, .., Yn). , Yn-) are formed independently, through which power is independently applied to each X-axis cell Xn and Y-axis cell Yn. 2 illustrates a state in which three points A, B, and C are touched.

3 is a flowchart illustrating a touch recognition method of the resistive multi-touch screen of FIG. 2.

[Read X-axis cell (S12)]

First, when power is applied to the touch screen, the touch screen enters the X-axis sensing mode for reading the X-axis data and waits for a touch to be made (S10). Herein, the sensing mode refers to a mode in which the position of the touch cell can be simply read. When a touch is made while waiting for a touch in the X-axis sensing mode (S10) (S11), a clock is supplied at this time and X-axis data is sensed to read an X-axis cell (S12). This keeps the clock free during touch standby, minimizing power consumption.

The X-axis cell reading step S12 includes a process of separating the cells in consideration of adjacent cells. In other words, adjacent cells are processed as a bundle instead of each sequence. In FIG. 2, since the X1 and X2 cells are sensed simultaneously by the touch point A, the following sequence is processed by sensing the two cells, that is, the X1-X2 cells and the X4 cells by combining the X1 cell and the X2 cell as one bundle. do.

[Read Y-axis cell (S13)]

After the X-axis cell reading (S12) is finished, the X-axis sensing mode to read the Y-axis data is switched, and the clock is supplied to read the Y-axis cell (Yn) for each X-axis cell (Xn). To this end, only the X1 and X2 cells are enabled and the remaining cells are disabled. In addition, data of the entire Y-axis cell Yn is sensed by the X1 electrodes X1 + and X1- and the X2 electrodes X2 + and X2- to read the Y-axis cell (S13). Then, the Y2, Y3, and Y5 cells are sensed. In this case, as in the X-axis cell reading step S12, the adjacent cells are considered in consideration of separation. Therefore, two cells, that is, cells Y2-Y3 and Y5 are sensed, and two touch points A and B are sensed.

[Read coordinate value of touch point A (S14)]

Apply power to X1 +, X2 + and X1-, X2- electrodes to read coordinates of touch point A, read voltage from Y2 + Y3 +, read X coordinate value of touch point A, and apply power to Y2 + Y3 + and Y2- Y3- The coordinate value of Y of the touch point A is read by reading the voltage at X1 + X2 + (S14). Here, the coordinate value of the touch point A means an analog-to-digital converter value.

[Sensing Point Verification (S15)]

To check if the data of touch point A is in place, switch back to X-axis sensing mode and Y-axis sensing mode, and go back through X-axis cell and Y-axis cell reading process (S12, S13) to see if the data is still there. To judge.

If the sensing data is changed while reading the coordinate value of the touch point A (S14), it is determined as an abnormal coordinate, and if the sensing data is in its position, the next sequence is performed. This is because the touch point is already somewhere between sensing the touch cell in the X-axis cell reading (S12) and Y-axis cell reading (S13) and reading the coordinate value of A in reading the coordinate value of touch point A (S14). This is to prevent the actual coordinates from being read by changing.

[Check position range (S16), check normal data (S17)]

In this process, the reference range for each of the X-axis and Y-axis cells (Xn, Yn) is determined in advance so that the coordinate values of the cells sensed in the X-axis cell reading step S12 and the Y-axis cell reading step S13 are set to the position. In the process of determining whether it is within a range, if the coordinate value is within the position range, it is determined that the coordinate value is virtual data, and if it is outside the position range, the coordinate value is determined to be virtual data.

For example, if there are 10 Y-axis cells (Yn),

Data in cell Y1 is in the range 0-1/10 of the entire coordinate value

Data in cell Y2 is in the range of 1/10 to 2/10 of all coordinates

Data in cell Y3 ranges from 2/10 to 3/10 of the coordinate

.

.

.

Data in cell Y10 ranges from 9/10 to 10/10 of all coordinates

In the case of point A, the X coordinate is determined to be in cells Y2 and Y3, and it is in the range of 1 / 10-3 / 10. The Y coordinate is determined to be in cells X1 and X2, and it is within 0 / 10-2 / 10. It is judged that it is normal data. If the actual coordinate value read out is out of this range, it is determined as error data (virtual data) and discarded.

[Save coordinate value of touch point A (S18)]

When the touch point A is recognized as normal data through the position range check (S16) (S17), it is stored as the coordinate value of the touch point A (S18).

[About touch point B (S19)]

When the coordinate value of the touch point A is stored (S18), since two cells, that is, the Y2-Y3 cell and the Y5 cell are sensed in the process of reading the preceding Y-axis cell (S13), the touch point, that is, the intersection of the X2 cell and the Y5 cell, is touched. The coordinate values for point B are stored in the same process as S14 to S18.

[Touch Point C (S20)]

If there is no other sensing data of Y cells for X1 and X2 cells, jump to Y axis cell reading step (S13), switch to Y axis sensing mode to read Y axis data, and supply clock to supply only X4 cells. Enable and disable the remaining cells. Data is sensed for the entire Y-axis cell Yn at the X4 electrodes X4 + and X4- to read the Y-axis cell (S13). Then, the Y2, Y3, and Y5 cells are sensed. In this case, the cells are separated in consideration of the adjacent cells. Therefore, two cells, that is, cells Y2-Y3 and Y5 are sensed, and two touch points D and C are sensed. In this case, the touch point D is a virtual touch point that is not actually touched but is recognized as a touch point.

In the process of going through S14 to S18 for the touch points C and D, the coordinate value of the touch point D is determined to be virtual data in the position range checking step 16, and is filtered. Only the coordinate values of the touch point C are stored.

FIG. 4 is a diagram for explaining the reason why the coordinate value of the virtual touch point D is determined as error data (virtual data) and filtered. As shown in FIG. 4, when the voltage is applied to X4 + and X4- to obtain the X coordinate value of the virtual touch point D and data is read from YY1, the X coordinate of the touch point C is read, which is Y2 in the case of X coordinate. This is outside the Y3 cell range (1 / 10-3 / 10). In addition, to obtain the Y coordinate value of the virtual touch point D, voltage is applied to Y2 +, Y3 +, Y2- and Y3-, and the voltage is read from XX2, and the Y coordinate of touch point A is read. / 10-4 / 10). Therefore, instead of the coordinate value of the virtual touch point D, the coordinate value of the touch point B (X coordinate of C, Y coordinate of A) is obtained. Accordingly, the virtual touch point D is determined to be an abnormal coordinate value in the position range checking step 16.

According to the multi-touch recognition method according to the present invention as described above, multi-touch recognition is possible, and the virtual touch coordinates can be filtered through the position range checking step, thereby eliminating the touch determination error. The power consumption is reduced because the clock is supplied until the touch is made in the sensing mode and the touch is made.

1 is a view for explaining a conventional resistive touch screen;

2 is a block diagram of a multi-touch screen for explaining a multi-touch recognition method of a resistive multi-touch screen according to the present invention;

3 is a flowchart illustrating a touch recognition method of the resistive multi-touch screen of FIG. 2;

FIG. 4 is a diagram for explaining the reason why the coordinate value of the touch point D is determined as the virtual data and filtered.

<Description of reference numbers for the main parts of the drawings>

X: X-axis resistive film Y: Y-axis resistive film

X +, X-, Y +, Y-: electrode Xn: X-axis cell

Yn: Y-axis cell

Claims (4)

A plurality of X-axis cells partitioned at regular intervals horizontally and a plurality of Y-axis cells partitioned at regular intervals vertically overlap so that touch cells are arranged in a matrix form, wherein each of the X-axis cells and Y-axis cells In both ends of the X-axis electrode and the Y-axis electrode is formed independently, and relates to the touch recognition method of the resistive type multi-touch screen in which the position range of the X-axis and Y-axis cells is set in advance, A first step of waiting in a sensing mode in which the X-axis data can be read; A second step of supplying a clock to sense X-axis data and reading an X-axis cell when a touch is made; A third step of switching to a Y-axis sensing mode in which Y-axis data can be read; A fourth step of supplying a clock to read Y-axis cells for each of the X-axis cells; A fifth step of reading coordinates of the touch point through the X-axis electrode and the Y-axis electrode; A sixth step of checking whether the data of the touch point read in the fifth step is in place by switching back to the X-axis sensing mode and the Y-axis sensing mode; If it is confirmed in step 6 that the data of the touch point is in place, it is determined whether the coordinate value read in step 5 is included in the position range of the touch cell read in step 4 and the coordinate value. The seventh step of judging and storing as a normal coordinate value if the position range is within the position range, and discards it by determining that it is a virtual coordinate value outside the position range; Touch recognition method of a resistive touch screen . The method of claim 1, wherein when another touch point other than the touch point is present, if the other touch point is on the same X axis cell as the touch point, the step after the fifth step is performed for the other touch point. Touch recognition method of a resistive multi-touch screen characterized in that. The method of claim 1, wherein if another touch point other than the touch point exists, and if the other touch point is on an X axis cell different from the touch point, the step after the fourth step is performed for the other touch point. Touch recognition method of a resistive multi-touch screen characterized in that. The method of claim 1, wherein the reading of the cell in the second step or the fourth step is performed in the case of adjacent cells, in which each cell is processed as a bundle instead of each sequence. Touch recognition method.

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