KR20160062539A - Method for judging intention of tiuch, computer program and touch panel type electronic device - Google Patents

Abstract

The present invention relates to a method for determining the intention of a touch, a computer program, and a touch panel type electronic device. According to one embodiment of the present invention, provided is a method for determining the intention of the touch, in which a touch cell group, which is formed by individually grouping effective touch cells having a touch value equal to or more than a reference touch value depending on touches onto a touch panel, is determined and scanned in each column direction and each row direction. A concave transaction is determined depending on the number of transactions traversing a touch boundary detected according to a scan result, the concave transaction having an ineffective touch cell having a touch value less than the reference touch value and inserted into the effective touch cells. Accordingly, it is determined whether or not a relevant touch cell group is intended. In addition, a computer program and a touch panel-type electronic device are suggested.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of judging intentions of a touch, a computer program and a touch panel type electronic apparatus,

The present invention relates to a method for intuitively determining a touch, a computer program, and a touch panel type electronic apparatus. A computer program, and a touch panel type electronic device, which determine whether a touch is an intentional touch or an intentional touch based on a degree of inclusion of a concurrent transaction with respect to a touch cell group.

With the recent development of portable electronic devices, the use of touch panels in electronic devices is increasing. Especially, in case of smartphone or tablet PC, touch panel is very important part. Furthermore, accepting multi-touch input from smart phones or tablet PCs is becoming commonplace.

Generally, a finger or a stylus touch device is used for touch input on a touch panel. However, when a multi-touch input is received from the touch panel, an incorrect touch or intention is not obtained when a finger or a stylus pen is used, but the touch may be performed due to a palm, a fingertip, or a finger fracture. Since unintended touches perform unintended commands with unnecessary input, it is necessary to prevent unintended touches from being performed to perform touch input.

Conventionally, when the number of valid touch cells in the touch cell group grouped by the effective touch cell equal to or larger than the reference touch value exceeds the set reference value or does not meet the set minimum reference value, So that the input is not performed.

However, even when the number of effective touch cells in the grouped touch cell group is within the setting reference range, for example, an unintended touch by a palm, a finger side, a finger fracture, a clothes sleeve or the like can be inputted.

U.S. Published Patent Application No. US 2012 / 0158629A1 (published on June 21, 2012) Korean Patent Publication No. 10-2005-0065943 (published on June 30, 2005)

In order to solve the above-mentioned problem, the present invention proposes a technique for determining whether a touch is an intentional touch or an intentional touch based on the degree of inclusion of a concurrent transaction with respect to a touch cell group, I want to.

In order to solve the above problems, according to one aspect of the present invention, a touch cell group in which effective touch cells having a reference touch value or more are independently grouped is determined according to a touch on the touch panel, And detects a transition that crosses the touch boundary, determines the transition detection result, and judges whether or not the touch cell group is unintended based on the inclusion degree of the concave transition in which the invalid touch cell less than the reference touch value is interposed between the valid touch cells There is proposed a method for judging whether a touch is intended (intentionless) or intent to judge whether the touch is an intended touch.

At this time, the touch bounding box is determined to include each touch cell group one by one, and the touch bounding box is scanned along each column and row direction to detect a transition.

Also, in one example, the number of valid touch cells belonging to each touch cell group is calculated, and it can be determined as a valid touch cell group when the number of valid touch cells belongs to the setting reference range.

In addition, in one example, scan progress is stopped when a concave transition is determined according to a transition detection result for each column or row, and a corresponding touch cell group determined to include a concave transition may be determined as a non-intentional touch. As a result of detecting all the transitions for each column and each row, if the concave transition is not included, it can be determined that the touch is intended.

Alternatively, in another example, the transition detection result for each column and the entire row, the number of concave transitions, and the number of convex transitions in which the invalid touch cell does not intervene between the valid touch cells are distinguished from each other, If the ratio of the number of concave transitions to the sum of the convex transitions is equal to or larger than a preset reference, the touch cell group can be determined as a touch of unintendedness. If the ratio of the number of convex transitions to the total of the concave and convex transitions in the touch cell group is equal to or greater than a preset reference, the touch cell group can be determined as the intended touch.

Next, in order to solve the above-described problem, each step of the method for intuitiveness determination of the touch according to the above-described examples is executed in combination with the arithmetic processing device of the electronic device having the touch panel as another aspect of the present invention A computer program stored on a storage medium of an electronic device is proposed.

Next, in order to solve the above-mentioned problem, another aspect of the present invention provides a touch value calculating unit for calculating a touch value according to a touch on a touch panel; A group setting unit for respectively determining a touch cell group in which effective touch cells equal to or larger than a reference touch value are independently grouped; A transition detection unit that scans each touch cell group along each column and row direction and detects a transition across the touch boundary; (Unintended) touch for the corresponding touch cell group based on the degree of inclusion of the concave transition in which the invalid touch cell less than the reference touch value is interposed between the valid touch cells by judging the detection result of the transition And an intentionality judging unit for judging whether or not the touch is judged to be a touch.

At this time, the group setting unit may calculate the number of valid touch cells belonging to each touch cell group, and may determine a valid touch cell group if the number of valid touch cells falls within the setting reference range. At this time, when the number of valid touch cells is out of the setting reference range, the touch cell group can be determined as unintended touch.

Further, in one example, the transition detection unit stops the scan progress when it is judged that the scan is a concave transition in the intent determination unit for each row or row in the scan along each column and row direction, and the intentional determination unit is concave The touch cell group determined to include the transition can be determined as a non-intentional touch.

Alternatively, in another example, the transition detection unit may be configured such that the intentional determination unit divides the number of concave transitions and the number of convex transitions in which no invalid touch cell is interposed between the valid touch cells, When the ratio of the number of concave transitions to the sum of the concave and convex transitions in the touch cell group is equal to or larger than a preset reference value, the touch cell group can be determined as an unintended touch. At this time, the intent determining unit calculates the ratio of the number of concave transitions in all the rows in the row and the row direction of the touch cell group or only in one direction of the column or row having the transition determined as the concave transition, Can be determined.

According to one embodiment of the present invention, it is possible to determine whether the touch is intentional or not, based on the degree of inclusion of the concurrent transaction with respect to the touch cell group, so that the touch input can not be performed in the case of unintentional touch.

Various effects according to various embodiments of the present invention may be understood and derived by those skilled in the art from a combination of the configurations of the embodiments without being directly referred to.

FIG. 1 is a flowchart schematically illustrating a method for intuitively determining a touch according to an embodiment of the present invention.
FIG. 2 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention.
FIG. 3 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention.
4 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention.
5 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention.
6A and 6B are block diagrams schematically showing a touch panel type electronic apparatus according to another embodiment of the present invention.
7A is a diagram schematically showing a touch cell group according to an example of a touch intended in a touch panel.
FIG. 7B is a diagram schematically showing a transaction according to row and row direction scans for the touch cell group of FIG. 7A.
8A is a view schematically showing a touch cell group according to an example of unintended touches on the touch panel.
FIG. 8B is a diagram schematically illustrating a transaction according to the column direction scan for the touch cell group of FIG. 8A.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing the configuration of a first embodiment of the present invention; Fig. In the description, the same reference numerals denote the same components, and a detailed description may be omitted for the sake of understanding of the present invention to those skilled in the art.

It should be noted that, even though a singular expression is described in this specification, it can be used as a concept representing the entire constitution unless it is contrary to, or obviously different from, or inconsistent with the concept of the invention. It is to be understood that the words "comprising", "comprising", "comprising", etc. in this specification are to be understood as the presence or addition of one or more other elements or combinations thereof.

A method of determining the intent of a touch according to one aspect of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a flowchart schematically illustrating a method of determining intentions of a touch according to an embodiment of the present invention. FIG. 2 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention FIG. 3 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention, and FIG. 4 is a diagram schematically showing a method of determining intentions of a touch according to another embodiment of the present invention And FIG. 5 is a flowchart schematically illustrating a method of determining intentions of a touch according to another embodiment of the present invention.

FIG. 7A is a view schematically showing a touch cell group according to an example of a touch intended in a touch panel, and FIG. 7B is a view schematically showing a transaction according to row and row direction scans for the touch cell group in FIG. 7A. FIG. 8A is a view schematically showing a touch cell group according to an example of unintended touches in a touch panel, and FIG. 8B is a view schematically showing a transaction according to a column direction scan for the touch cell group in FIG. 8A.

1 to 5, a touch intent determination method according to one example includes a touch value calculation step S100, a touch cell group determination step S300, S301, and S303, a transition detection step S500, S501, and S503 (S700, S701, S703, S705) whether or not the unintended touch is performed. At this time, the intention determination method of the touch is a method for determining whether the intention of a touch on the touch panel (refer to reference numeral 5 in Figs. 6A and 6B), that is, whether it is an unintended touch or an intended touch. Referring to the drawings, each step will be described in detail.

Referring to FIGS. 1 to 5, in a touch value calculation step S100, a touch value of each touch cell is calculated according to at least one touch of the touch panel 5. At this time, at least one touch to the touch panel 5 is performed. The touch to the touch panel 5 can be performed not only by a finger or a stylus touch device but also by a palm, a fingertip, a finger joint, or the like. A touch to the touch panel 5 may include an intended touch as well as an unintended touch. Or a touch to the touch panel 5 may include only an unintended touch. Therefore, it is necessary to judge whether the touch on the touch panel 5 is an unintended touch or an intended touch.

Referring to FIGS. 7A and 8A, touch values corresponding to touched touch cells constituting the touch panel 5 are illustrated. Here, the touch values shown in Figs. 7A and / or 8A are illustrative and not restrictive. The calculation of the touch value in each touch cell can be calculated by detecting, for example, a voltage value according to a touch. The concrete method of calculating the touch value is not an object to be solved by the present invention. In the present invention, since it is easy to determine whether or not the touch is calculated with the touch value calculated by various methods, a concrete method of calculating the touch value And the description thereof will be omitted.

Next, referring to FIGS. 1 to 5, at least one or more touch cell groups in which effective touch cells equal to or greater than a reference touch value are independently grouped are determined in a touch cell group determination step (S300, S301, S303). The touch values calculated according to the touch of the touch panel 5 are compared with the reference touch values and the touch cells having valid touch values are used as the effective touch cells. The reference touch value can be determined by an appropriate value obtained through an experimental operation. At this time, the reference touch value determines the boundary of the touch cell group. The effective touch cells having a reference touch value or more are grouped to be adjacent and independent to form a touch cell group. Not only two or more touches on the touch panel 5 but also two or more touch cell groups may be determined according to the reference touch value even by a single touch action.

For example, referring to FIGS. 7A and 8B, when the reference touch value is 70 and the touch cells having a touch value of 70 or more are used as effective touch cells and the touch cells having a touch value of less than 70 are used as invalid touch cells, Are displayed. 7A and 8B, one touch cell group is determined. However, a plurality of touch cell groups may be formed for at least one touch of the touch panel 5. FIG. 7A to 8B, touch cell groups having a reference touch value or more are surrounded by thick solid lines of touch boundaries to form independent groups.

For example, referring to FIG. 3, in one touch cell group determination step S303, a touch value of each touch cell is calculated. After the touch cell is divided into valid touch cells belonging to each touch cell group independently grouped The number is calculated (S313). If the calculated number of the valid touch cells belongs to the setting reference range, the touch cell group is determined as an effective touch cell group to be subjected to the intention determination of the scan and touch at a later step (S333). For example, only when the number of effective touch cells in the independently grouped touch cell group, that is, the number of touch cells having a reference touch value or more corresponds to a range not more than the maximum number in accordance with the set reference range, It is possible to detect a concave transition at a subsequent step only when the range is equal to or less than the maximum number and judge whether the touch cell group is an unintended touch or an intended touch.

For example, if the number of effective touch cells calculated in the touch cell group determination step S303 is out of the setting reference range, the touch cell group may be determined as an unintended touch without going through the transition detection step S500 (S600). For example, if the number of effective touch cells in the independently grouped touch cell group is greater than the predetermined maximum number, then the touch cell group may be determined as an unintended touch have. Alternatively, if the number of effective touch cells in the independently grouped touch cell group is smaller than the preset minimum number, it is possible to determine that the corresponding touch cell group is an unintended touch without searching for a concave transition at a later step.

Referring to FIG. 2, in one touch cell group determination step S301, at least one touch boundary box including each determined touch cell group may be determined. At this time, the touch bounding box may be one for preliminarily limiting the scan range in each column and row direction in a later step. For example, referring to FIG. 8A, the touch bounding box including one touch cell group may be a convex polygon, for example, a rectangular box. At this time, the respective sides of the rectangular touch bounding box may coincide with the outermost boundaries in the column and row directions of the touch cell group. Alternatively, although not shown, each side of the rectangular touch bounding box may be formed on the outermost perimeter of the touch cell group, for example, by one touch cell.

Next, the transition detection steps S500, S501, and S503 will be described with reference to FIGS. In the transition detection steps (S500, S501, S503), each touch cell group determined in the touch cell group determination step (S300, S301, S303) is scanned along each column and row direction. At this time, at least the maximum vertical width of the touch cell group is scanned in the column direction scanning, and at least the maximum width of the touch cell group is scanned in the row direction scanning. Accordingly, a transition that crosses the boundary of the touch boundary, that is, the touch cell group, is detected at the time of scanning. In the present invention, the term " crossing the boundary of the touch boundary, that is, the touch cell group includes not only the case of completely dividing the boundary of the touch boundary, i.e., the touch cell group, but also the case of vertically meeting at the boundary of the touch boundary, . That is, in FIG. 8B, in the case of a scan starting vertically at the touch boundary, that is, at the boundary of the touch cell group, the touch boundary, that is, the point perpendicular to the boundary of the touch cell group becomes a transition.

Referring to FIGS. 7B and / or 8B, according to the scan for the touch cell group, a transition that crosses the touch boundary, that is, the boundary of the touch cell group, can be detected. For example, transition detection can be performed by determining the boundaries of the touch cell groups at the time of touch cell group setting as shown in Figs. 7A and / or 8A, and by dividing the number of points crossing the touch boundary, The number of transitions can be detected. Alternatively, a transition may be detected when an effective touch cell having a reference touch value equal to or greater than a reference touch value and an invalid touch cell having a reference touch value less than the reference touch cell are adjacent to each other in the scan direction.

Referring to FIG. 7B, two transitions can be detected for each column and row in the column direction scan and the row direction scan for the touch cell group, respectively. Alternatively, referring to FIG. 8B, columns having two transitions and columns having four transitions are detected in the column direction scan for the touch cell group. This feature is due to the nature of the straight line traversing the convex polygon and the concave polygon. The convex polygon is always located inside the convex polygon when the line connecting the neighboring two sides or the neighboring two sides is always drawn because the size of the interior angle at each vertex is always smaller than 180 degrees. Therefore, drawing a straight line across two sides of a convex polygon does not meet the other sides of the convex polygon but only meets two sides. Also, in a concave polygon, the internal angle of the concave portion is greater than 180 degrees, so that when a straight line is drawn across the neighboring two sides, the other sides of the remaining sides are also encountered. Thus, in the case of a concave polygon, it is possible to construct a straight line that meets four sides. That is, in FIG. 7B, as in the case of the convex polygon, a straight line traversing the convex polygon always forms two transitions, and in FIG. 8B, a straight line traversing the neighboring sides of the concave portion, like the concave multi- Four different transitions are formed because the other two sides are traversed at the same time.

For example, referring to FIG. 2, in the transition detection step S501, each touch bounding box determined in the touch cell group determination step S301 is scanned along each column and row direction, and a transition can be detected. The touch bounding box may have a square shape, for example, and each side may coincide with an outermost boundary in the row and column direction of the touch cell group. At this time, when scanning is performed along each column and row direction of the touch bounding box, a transition traversing the boundary of the touch cell group can be detected.

For example, in one example, each column and row scan for a touch cell group may be performed by sequential scanning in each row direction after each column direction, or vice versa, or by alternately sequentially scanning each column and row direction alternately. For example, referring to FIG. 4, a touch cell group may be sequentially scanned one by one in a column or a row direction, or alternatively, a column and a row may be alternately scanned one by one (S513). Referring to FIG. 4, in one example, if it is determined in step S703 that the unintended touch is determined according to the transition detection result for each column or row (S713) (S533). At this time, if it is determined that the scan result in the corresponding column or row is a concave transition (S713), the touch cell group including the column or row is determined as an unintended touch (S733).

Alternatively, referring to FIG. 5, in one example, in the transition detection step (S500), a touch cell group may be scanned in all the columns and row directions, and a transition may be detected. For example, as shown in FIG. 7B, all the touch cells are scanned in the column and row directions, and a transition can be detected. Alternatively, if it is determined that the concave transition is determined in the step of determining whether or not the touch screen is touched according to the result of the transition detection for each row or row, only the remaining columns or all the rows in the scanning direction are scanned, All are scanned and transitions can be detected. For example, as shown in FIG. 8B, when a concave transition having four transitions is detected in the scan direction in the column direction with respect to the touch cell group, the scan is performed only in the remaining column direction, and a transition may be detected. Of course, unlike the view of FIG. 8B, a scan for each column and row direction for the touch cell group is performed and a transition may be detected.

Next, with reference to FIG. 1 to FIG. 5, steps S700, S701, S703, and S705 for determining whether the unintended touch is performed will be described in detail. In step S700, S701, S703, and S705, it is determined whether or not there is a touch in the unintended touch. Based on the degree of inclusion of the concave transition in which the invalid touch cell is interposed between the valid touch cells, It is determined whether the touch cell group is an unintended (unintended) touch or an intended touch. At this time, the concave transition means that the invalid touch cell is interposed between the valid touch cells in one row in the column or row direction, and the transition to the invalid touch cell in the valid touch cell and the transition to the valid touch cell in the invalid touch cell . Alternatively, the concave transition refers to a case where four transitions are detected in one scan in the column or row direction as shown in FIG. 8B.

For example, referring to FIG. 8B, a convex transition having two transitions and a concave transition having four transitions can be detected for each row in the column direction scan for the touch cell group. At this time, the convex transition having two transitions is derived from the characteristic that a line connecting the two sides of the convex polygon is located in the convex polygon. Drawing a straight line across two sides of a convex polygon does not meet the other sides of the convex polygon but only meets two sides. Generally, in the case of an intended touch, the boundary shape of the touch cell group has a convex polygonal structure. Therefore, when only two transitions are detected from the characteristic of the convex polygon, the scan in the corresponding column or row becomes a convex transition. For example, in the case of an intended touch, the boundary shape of the touch cell group may be a rectangular shape, or may be an elliptic-like convex polygon having a major axis length and a minor axis length different from each other, or may be a convex polygon similar to a circular shape. Also, in a concave polygon, the internal angle of the concave portion is greater than 180 degrees, so that when a straight line is drawn across the neighboring two sides, the other sides of the remaining sides are also encountered. Depending on the characteristics of the concave polygons, a concave transition is formed when there are four transitions. Generally, since the touch cell group having such a concave polygonal structure is highly likely to be an unintended touch, according to the present invention, it is determined that the unintended touch is determined according to the inclusion degree of the concave transition.

For example, referring to FIG. 8B, in one example, when determining whether or not the touch screen has a touch screen, when determining the transition detection result for each column and each row, if the number of transitions is 4 or more, If the number of transitions is equal to or greater than two, or if an up transition from the invalid touch cell to the effective touch cell occurs continuously after the down transition, the transition detection result of the corresponding column or row is determined as the concave transition.

For example, referring to FIG. 2, it can be determined whether the touch cell group in the touch bounding box is an unintended touch or an intended touch based on the degree of inclusion of the concave transition in the step of determining whether there is an unintended touch (S701) .

Referring to FIG. 4, in an unintended touch determination step S703, the transition detection result is sequentially determined for individual columns or rows, and a transition detection result is stored in the invalid touch cells (S713), the scan progress in the remaining column and / or row direction is stopped in the transition detection step S503 (S533). At this time, in the non-intention touch determination step S703, the corresponding touch cell group determined to include the concave transition is determined as the unintended touch (S733).

Continuing with reference to FIG. 4, in the non-intuit touch determination step S703, if the result of transition detection for each column and the entire row does not include the concave transition, the touch of the corresponding touch cell group dl (S753).

5, in the non-intention touch determination step S705, the number of concave transitions and the number of convex transitions in which invalid touch cells are not interposed between the valid touch cells And the ratio of the number of concave transitions to the sum of the concave and convex transitions in the touch cell group is calculated (S715). At this time, if the ratio of the concave transition is equal to or larger than the preset reference, the touch cell group is determined as a touch of unintendedness (S735). If the ratio of the concave transition is less than the preset reference, the touch cell group can be determined as the intended touch (S755).

For example, since the touch shape is determined after the reference touch value is applied, the recorded touch shape after application of the reference touch value for the intended touch due to touch or hovering may not be exactly convex polygonal shape. At this time, a very small number of concave transitions may be detected for some scans, where the total number of concave transitions will be smaller than the shape of a fully swollen concave polygon as shown, for example, in FIG. 8B. Therefore, in order to clarify the touches in such a case, it is possible to judge whether the unintended touch is performed with the ratio of the number of concave transitions to the sum of the concave and convex transitions in the touch cell group. That is, if the ratio of the number of concave transitions to the sum of the concave and convex transitions is equal to or greater than a preset reference, it is determined that the touch is an unintended touch. If the ratio is less than a preset reference, the touch can be determined to be the intended touch. At this time, the preset reference can be estimated by selecting an appropriate value from the results obtained through the experimental method.

5, in the non-intention touch determination step, the number of concave transitions and the number of convex transitions in which invalid touch cells are not interposed between the valid touch cells And the ratio of the number of convex transitions to the sum of concave and convex transitions in the touch cell group can be calculated. At this time, if the ratio of the calculated convex transitions is equal to or greater than a preset reference, the touch cell group can be determined as an intended touch.

Next, a computer program according to another aspect of the present invention will be described. The computer program according to one example is combined with an arithmetic processing unit (processor) of an electronic device having a touch panel 5 to execute each step of the method for intuitively determining a touch according to one example of the above-described invention. At this time, the computer program is stored in the storage medium of the electronic device having the touch panel 5. The computer program performs each step in the embodiment of the intention determination method of the touch described above, so that a detailed description will be made with reference to the above-described method of determining the intention of the touch.

For example, in the transition detection step S503 of each step of the touch intention determination method executed by the computer program, the transition is detected in each column and row direction, and the transition is detected according to the result of transition detection for each column or row If it is determined in step S703 that the non-affinity touch is determined to be a concave transition (S713), the scan process is interrupted (S533). In this case, in step S703, it is determined that the corresponding touch cell group determined to include the concave transition is a non-intentional touch in step S733.

5, in one example, in the transition detection step (S500) of each step of the touch intention determination method executed by the computer program, all the scan is performed along each column and row direction, and a transition is detected do. At step S705, it is determined whether or not the touch cell is interrupted between the number of concave transitions and the number of the effective touch cells, The ratio of the number of concave transitions to the total of the concave and convex transitions in the corresponding touch cell group is calculated by dividing the number of convex transitions (S715). If the ratio of the concave transition is equal to or larger than the predetermined reference, the touch cell group is determined to be the unintended touch (S735).

Next, a touch panel type electronic device according to another embodiment of the present invention will be described in detail with reference to the drawings. Hereinafter, a method for intuitively determining a touch according to embodiments of one aspect of the present invention described above and FIGS. 1 to 5, 7a to 8b will be referred to, and redundant explanations can be omitted. Here, reference numerals not shown in the drawings to be referred to may be reference numerals in other drawings showing the same configuration.

6A and 6B are block diagrams schematically showing a touch panel type electronic apparatus according to another embodiment of the present invention.

6A and 6B, a touch panel type electronic apparatus according to one example includes a touch panel 5, a touch value calculation unit 10, a group setting unit 30, a transition detection unit 50, And an intentional determination unit 70. Each configuration will be described in detail with reference to the drawings.

The touch panel 5 receives an input signal by an electrostatic method or a static pressure method according to a touch of a finger, a stylus touch device, or the like.

Referring to FIGS. 6A and / or 6B, the touch value calculation unit 10 calculates the touch value of each touch cell according to at least one touch of the touch panel 5.

Next, referring to FIGS. 6A and 6B, the group setting unit 30 determines at least one or more touch cell groups in which valid touch cells having a reference touch value or more are independently grouped.

For example, in one example, the group setting unit 30 calculates the number of valid touch cells belonging to each touch cell group in which the effective touch cells are independently grouped. At this time, when the number of valid touch cells belongs to the setting reference range, the group setting unit 30 sets the valid touches to be subjected to intentional determination in the scanning and intent determining unit 70 in the transition detecting unit 50 It can be determined as a cell group.

If the number of valid touch cells calculated by the group setting unit 30 is out of the set reference range, the intent determining unit 70 may determine that the touch cell group is an untouched touch.

6A and / or 6B, the transition detection unit 50 scans each touch cell group determined in the group setting unit 30 along each column and row direction, and detects a transition across the touch boundary do.

For example, in one example, the transition detection unit 50 can scan all along each column and row direction and detect a transition.

Further, in one example, the transition detection unit 50 scans along each column and row direction and detects a transition, and according to a result of detection of a transition on a row-by-column or row-by-row basis, It is possible to stop the scan process for the remaining columns and / or rows.

In another example, when it is determined by the intent determining unit 70 that a concave transition is determined in accordance with a result of transition detection for each column or row, only the remaining column or all of the rows in the scanning in-progress direction are scanned, And the transition can be detected.

6A and 6B, the intentionality determining unit 70 determines the result of detection of the transition, and determines the inclusion degree of the concave transition in which the invalid touch cell less than the reference touch value is interposed between the valid touch cells (Unintended) touch or intended touch with respect to the corresponding touch cell group.

In addition, in one example, when the number of transitions is four or more, or when the number of the downward transitions from the effective touch cell to the invalid touch cell is two or more Or when the up transition from the invalid touch cell to the valid touch cell occurs continuously after the down transition, the transition detection result of the corresponding column or row can be determined as the concave transition.

For example, in one example, the intent determination unit 70 may determine a recessed transition in which an invalid touch cell less than a reference touch value is interposed between valid touch cells according to a transition detection result for each column or row. At this time, the scan progress is stopped in the transition detecting unit 50 in accordance with the determination of the concave transition for the individual column or the row, and the intention determining unit 70 sets the corresponding touch cell group determined to contain the concave transition as non- Can also be judged by touch.

In another example, the intent determining unit 70 divides the number of concave transitions and the number of convex transitions in which no invalid touch cell is interposed between the valid touch cells, for each column and the whole row, The ratio of the number of concave transitions to the sum of the concave and convex transitions in the cell group can be calculated. At this time, if the ratio of the concave transition is equal to or higher than a preset reference, the intentional determination unit 70 can determine the touch cell group as an unintended touch. If the ratio of the concave transition is less than a preset reference, the touch cell group can be determined as an intended touch.

The foregoing embodiments and accompanying drawings are not intended to limit the scope of the present invention but to illustrate the present invention in order to facilitate understanding of the present invention by those skilled in the art. Embodiments in accordance with various combinations of the above-described configurations can also be implemented by those skilled in the art from the foregoing detailed description. Accordingly, various embodiments of the present invention may be embodied in various forms without departing from the essential characteristics thereof, and the scope of the present invention should be construed in accordance with the invention as set forth in the appended claims. Alternatives, and equivalents by those skilled in the art.

5: touch panel 10: touch value calculating unit
30: Group setting unit 50: Transition detection unit
70: Intentional judgment unit

Claims (17)

Calculating a touch value of each touch cell according to at least one touch of the touch panel;
Determining at least one or more touch cell groups in which effective touch cells having a reference touch value or more are independently grouped;
Scanning each determined touch cell group along each column and row direction and detecting a transition across the touch boundary; And
Determining whether or not the touch cell group is unintended (unintended) or not based on a degree of inclusion of a concave transition in which an invalid touch cell less than the reference touch value is interposed between the valid touch cells, And determining whether the touch is a touch.
In claim 1,
Wherein the step of determining each of the touch cell groups comprises the steps of determining at least one or more touch bounding boxes including each determined touch cell group,
In the detecting of the transition, each determined touch boundary box is scanned along each column and row direction, the transition is detected,
Determining whether the touch cell group in the touch boundary box is an unintended touch or an intended touch based on a degree of inclusion of the concave transition in the step of determining whether the touch is the unintended touch or the intended touch, How to judge sex.
In claim 1,
Wherein the step of determining the touch cell group comprises: calculating a touch value of each touch cell, calculating the number of the effective touch cells belonging to each touch cell group independently grouped by the effective touch cells, When the number of touch cells belongs to the set reference range, the touch cell group is determined to be an effective touch cell group to be subjected to the intention determination of the scan and the touch at a subsequent step.
In claim 1,
The number of transitions is not less than 4 or the number of down-transitions from the effective touch cell to the invalid touch cell is less than or equal to 4 when judging whether the touch is the unintended touch or the intended touch, 2 or more, or when the up transition from the invalid touch cell to the valid touch cell occurs continuously after the down transition, the determination result of the transition detection of the corresponding column or row is determined as the concave transition .
The method according to any one of claims 1 to 4,
The step of detecting the transition may include detecting the transition by scanning along each column and a row direction and determining whether the touch is an unintended touch or an intended touch according to a result of transition detection for each column or row, The scan progress is stopped,
Wherein the step of determining whether the non-intentional touch is an intentional touch is to determine a touch cell group determined to include the concave transition as an unintended touch.
The method according to any one of claims 1 to 4,
In the detecting of the transition, all the scanning is performed along each column and row direction to detect the transition,
The number of concave transitions and the number of convex transitions in which the invalid touch cell does not intervene are discriminated between the valid touch cells for each row and the whole row in the step of determining whether the touch is intended or not Calculating a ratio of the number of the concave transitions to the sum of the concave and convex transitions in the touch cell group and determining that the touch cell group is an unintended touch when the ratio of the concave transition is equal to or greater than a preset reference A method for judging intent of a touch.
The method according to any one of claims 1 to 4,
Determining whether the touch cell group is an unintended touch or an intended touch, if the transition detection result for each column and the row does not include the concave transition, the touch cell group is determined as an intended touch; A method of determining the intent of a touch.
The method according to any one of claims 1 to 4,
The number of concave transitions and the number of convex transitions in which the invalid touch cell does not intervene are discriminated between the valid touch cells for each row and the whole row in the step of determining whether the touch is intended or not Calculating a ratio of the number of the convex transitions to the total of the concave and convex transitions in the touch cell group and determining the touch cell group to be the intended touch when the ratio of the convex transition is equal to or larger than a preset reference Of the touch.
A computer program stored in a storage medium of an electronic device for executing each step of a method for judging intent of a touch according to any one of claims 1 to 4 in combination with an arithmetic processing device of an electronic device having a touch panel.
In claim 9,
Wherein the step of detecting the transition among the steps of the intentionality determination method executed by the computer program comprises the steps of detecting the transition by scanning along each column and row direction, When it is determined that the touch is an unintended touch or an intended touch,
Wherein the step of determining whether the unintended touch is an intentional touch among the steps of the intentional determination method includes determining whether the corresponding touch cell group is determined to include the concave transition by an unintended touch, program.
In claim 9,
In the step of detecting the transition among the steps of the intentionality judging method executed by the computer program, all the scanning is performed along each column and row direction to detect the transition,
Determining whether the unintended touch or the intended touch among the respective steps of the intentional determination method includes a step of determining whether or not the number of the inactive transitions and the number of the invalid touch cells The ratio of the number of the concave transitions to the sum of the concave and the convex transitions in the touch cell group is calculated, and when the ratio of the concave transitions is equal to or larger than a preset reference, Is determined as a non-intentional touch.
Touch panel;
A touch value calculating unit for calculating a touch value of each touch cell according to at least one touch of the touch panel;
A group setting unit for determining at least one or more touch cell groups in which effective touch cells equal to or larger than a reference touch value are independently grouped;
A transition detection unit that scans each determined touch cell group along each column and row direction and detects a transition across the touch boundary; And
Determining whether or not an unintended (unintended) touch is made to the touch cell group based on a degree of inclusion of a concave transition in which an invalid touch cell less than the reference touch value is interposed between the valid touch cells, And an intentionality judgment unit for judging whether or not the touch is intended,
And receives the intended touch as valid input except for the unintentional touch.
In claim 12,
Wherein the group setting unit calculates the number of valid touch cells belonging to each touch cell group grouped by the valid touch cells and if the number of valid touch cells falls within a set reference range, Wherein the intentional determination unit determines an effective touch cell group to be an object of intentional determination in the intentional determination unit.
In claim 13,
Wherein the intentional judging unit judges that the touch cell group is an untouched touch when the number of valid touch cells calculated in the group setting unit exceeds the set reference range.
In claim 12,
Wherein the intentional determination unit determines that the number of transitions is four or more when the transition detection result for each column and each row is determined or if the number of downtransitions to the invalid touch cell in the valid touch cell is two or more, And when the up transition from the invalid touch cell to the valid touch cell occurs, the determination result of the transition detection of the corresponding column or row is determined as the concave transition.
The method according to any one of claims 12 to 15,
The transition detection unit scans along each column and row direction and detects the transition. If it is determined that the concave transition in the intentionality determination unit is in accordance with the result of transition detection for each column or row, ,
Wherein the intentional determination unit determines the touch cell group determined to include the concave transition as an unintended touch.
The method according to any one of claims 12 to 15,
Wherein the transition detecting unit scans all along the column and row directions and detects the transition,
Wherein the intentional determination unit divides the number of the concave transitions and the number of the convex transitions in which the invalid touch cell is not interposed between the valid touch cells from each row and the whole row, Wherein the ratio of the number of the concave transitions to the sum of the concave and convex transitions is calculated, and when the ratio of the concave transition is equal to or larger than a predetermined reference, the touch panel group is determined as the unintended touch .

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