KR20110047556A - Method for controlling function of electronic device based on muti-touch input - Google Patents

Abstract

PURPOSE: An operation control method of an electronic device based on multi-touch input stroke feature data is provided to easily control the operation of an electronic device by the use of the stroke feature data and to increase the convenience of a user by simple operation control. CONSTITUTION: An electronic device receives two or more input strokes. The electronic device collects two or more feature data toward each of two or more input strokes(S100). Two or more input strokes include one or more contact input signal through the contact of a touch screen. The electronic device determines control operation based on the collected two or more feature data(S110).

Description

METHOD FOR CONTROLLING FUNCTION OF ELECTRONIC DEVICE BASED ON MUTI-TOUCH INPUT}

The present invention relates to a method of controlling an electronic device based on multi-touch input based stroke feature data. More particularly, the present invention relates to a multi-touch input based stroke input from a user in controlling an electronic device having a touch screen which also functions as an input means. The present invention relates to a method for allowing a user to perform a desired control operation simply and quickly based on the feature data.

In accordance with the development of related technologies, various electronic devices such as mobile phones, PDAs, computers, etc. omit conventional input means such as keypads, keyboards or mice, and input the output means such as LCDs to include sensors having a touch sensing function. Touch screens that also operate as a means are widely used. For example, in the conventional mobile communication terminal, a means such as a keypad is used, but the size of the terminal should be relatively small. Therefore, when the keypad occupies space, the space of the output means is reduced, and thus the keypad is omitted. Increasingly, the trend of adopting a touch screen so that most of the apparatus can also function as an output means is increasing. In this case, since the size of the output means is relatively wide, for example, when watching a video or watching TV, various services can be conveniently used through a wide screen.

However, the electronic device having such a touch screen has the above advantages, but when a user inputs a command for operating the electronic device, there is an inconvenience in that of the conventional keypad. For example, in the case of a mobile communication terminal, when making a call, a virtual keypad screen must be output on the touch screen and the number of the keypad screen must be accurately selected. It is true that there is a problem of a slight fall, and in view of these limitations, there is a demand for a method of more efficiently using a touch screen as an input means.

Also, recently, a so-called "multi-touch" input method has attracted attention, and the multi-touch input method is a method of simultaneously performing two or more touch inputs. When the multi-touch input method is used, a corresponding user input operation can be expanded, thereby enabling a wider graphical user interface. For example, in the graphic user interface illustrated in the display device, when a user rotates with two fingers, the window or frame is rotated, or when the user moves the fingers apart, the image is enlarged. This can be further increased and its frequency of use is gradually increasing.

On the other hand, as described above, in the case of implementing a variety of operation commands for controlling the operation of the electronic device having a touch screen with a touch input, in particular multi-touch input, there is a problem that the convenience is inferior from the user's point of view, this point is recently There is a need to provide a motion control method that can solve the problem based on the "multi-touch input" in which the range of use is expanded, but which does not impair the user's operation convenience.

The present invention has been made in view of the above limitations, and in controlling the operation of an electronic device having a multi-touch input function, the operation of the electronic device can be easily controlled using stroke feature data based on the multi-touch input. It is an object of the present invention to provide a method capable of improving user convenience.

In order to achieve the above object, the present invention provides a method for controlling the operation of an electronic device by multi-touch input-based stroke feature data in an electronic device having a touch screen. A first step of collecting at least two feature data for each of the at least two input strokes while receiving at least two input strokes comprising at least one contact input signal input via the second input stroke; Determining a control operation to be performed in the electronic device based on the collected at least two feature data; And a third step of performing the determined control operation, and controlling the operation of the electronic device according to the multi-touch input based stroke feature data.

Here, each of the at least two feature data in the first step may be classified based on the position where the contact input signal is made.

In addition, each of the at least two feature data in the first step may include interval information, which is time interval information between respective contact input signals, and duration, which is time information when each touch input signal contacts the touch screen. The information may be at least one of the information or a combination thereof.

In addition, the first step may be configured to be performed only in the case of a screen state of a predetermined touch screen and / or a predetermined screen area of the touch screen.

The second step may be performed based on each of the at least two feature data or combination information thereof.

The second step may include comparing each of the at least two feature data collected from the previously stored template feature database by comparing the previously stored template feature database with each of the collected at least two feature data or combination information thereof. Step 2-1 of retrieving template feature data having the same identity as their combined information; And determining a control operation set according to the retrieved template feature data as a control operation to be performed by the electronic device.

According to the present invention, in controlling the operation of an electronic device having a multi-touch input function, it is possible to easily control the operation of the electronic device using stroke feature data based on the multi-touch input, thereby improving user convenience. It may provide a method.

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

1 is a flowchart illustrating an embodiment of a method for controlling an operation of an electronic device based on multi-touch input based stroke feature data according to the present invention.

First, the electronic device to which the present invention is applied is an electronic device having a touch screen function such as, for example, an LCD, as an input and output device, and may be, for example, a computer, a mobile phone, an MP3 player, a navigation device, or an ATM.

In addition, the electronic device according to the present invention is a device capable of receiving a multi-touch input, that is, at least two or more touch inputs input from a user, interpreting the same, and performing a predetermined process, and the electronic device performs a multi-touch input function. A touch screen which can be provided is provided as an input device and an output device. Such a touch screen may use a technique known in the prior art, such as a resistive method, a capacitor method, an infrared method, and the like, and includes a configuration of software and hardware for processing such a multi-touch input although not shown inside the electronic device. . However, the specific configuration of the touch screen capable of performing the multi-touch input function and the internal configuration of the electronic device for processing the multi-touch input function from the touch screen are not directly related to the present invention, and also by the prior art. As it is obvious, detailed description is omitted. In addition, the electronic device to which the present invention is applied refers to a device that receives a command by a multi-touch input from a user and performs an operation corresponding to the received command. Such electronic devices are also widely used in the prior art, and their detailed configurations are not directly related to the present invention, and thus detailed descriptions thereof will be omitted.

The electronic device has at least two features for each of the at least two input strokes, each receiving at least two or more input strokes consisting of at least one or more touch input signals input from a user through a touch of a touch screen of the electronic device. Collect data (S100).

Here, the touch input signal refers to a touch operation such as a user pressing or tapping the touch screen with a finger or a touch pen, and the input stroke means at least one touch input input for a predetermined time. Means a set of signals. For example, if the user “tucks” the touch screen for a period of time and touches it three times in a row, the touch input signal means each of the three “tuck”, “tuck” and “tuck” signals, and the input stroke is the fixed time Each contact input signal input during the process can be defined as "Tak Tak". In the present invention, since at least two or more input strokes are received by the multi-touch input, for example, when the user taps the touch screen with a constant beat alternately or alternately using the index finger and the middle finger of the right hand, two input strokes are configured.

Further, in step S100, while receiving at least two or more input strokes as described above, feature data for each input stroke is collected. In the present invention, the characteristic data is defined as data describing the characteristics of the input stroke. The feature data can be used as long as it can describe the characteristics of the input stroke. For example, interval information, which is time interval information between the respective touch input signals, and each touch input signal is connected to the touch screen. At least one of the duration information or combination information thereof may be used.

For example, if the user inputs the touch screen four times in a certain time as shown in FIG. 2, the characteristic data of the input stroke “Taking” may be displayed as shown in FIG. 3. That is, the duration information may be (180, 190, 185, 176), and the interval information may be configured as (200, 220, 230). Of course, both duration information and interval information may be configured as feature data, and only one of them may be used as feature data. The invention collects at least two or more input strokes and collects feature data for each of them, as described above, each of which may be distinguished based on the location at which the contact input signal is made. For example, when a user taps the touch screen four times in turn at an interval between the index finger and the middle finger, the position where the index finger touches the touch screen and the position where the middle finger touches the touch screen are generally the first index and middle finger. Will be spaced similar to. Therefore, the coordinate values on the touch screen on which the touch input signal is generated by the detection and the coordinate values on the touch screen on which the touch input signal is generated by the middle finger can be distinguished from each other.

FIG. 4 is a diagram for explaining such a phenomenon. When a total of six touch inputs (three times each) are detected, the detection and the middle finger alternately spaced apart from each other at a predetermined interval, and show coordinate values on the touch screen.

As shown in FIG. 4, the area touched three times by the index finger is indicated by a circle A, and the area touched three times by the middle finger is indicated by a circle B, which can be separated from each other at regular intervals. Accordingly, the electronic device can group coordinate values close to each other based on the coordinate values of each input touch signal into one and distinguish input strokes based on the grouped coordinate values, and show characteristic data for each of these input strokes. 2 and 3, respectively, can be calculated.

On the other hand, if the touch screen has a pressure sensor function, pressure information when each touch input signal is input may also be collected and used as feature data.

On the other hand, the step (S100) may be performed only when the screen state of the predetermined touch screen. In general, when there is no input for a predetermined time, the touch screen of the electronic device is turned off or in a standby state in order to save power and prevent malfunction due to unintended contact of the user. In some cases, the touch screen may not operate even when a touch occurs. By using this, for example, the step S100 may be performed when the touch screen is in an off state, or may be configured to perform step S100 when the touch screen is in a standby state. Of course, it may be configured to perform the step (S100) even when the touch screen is activated. Importantly, the electronic device sets whether to perform the step S100 according to the screen state of the touch screen, and performs the step S100 only in the set state. In this configuration, for example, if the electronic device is a mobile phone, and set to call a specific person for a specific input stroke based on multi-touch, in order to make a call to a specific person in the idle screen state, Without the hassle of going through a menu screen of several steps, an operation such as making a phone call can be performed by inputting only a specific input stroke in the standby screen state.

Meanwhile, the step S100 may be configured to be performed only when an input stroke is received for a predetermined screen area of the touch screen. For example, if the user inputs an input stroke in a predetermined area (for example, four corner areas) regardless of what the screen state of the touch screen is, the step S100 is performed regardless of the screen state of the current touch screen. It can also be configured to. Of course, as described above, it may be configured to perform the step (S100) in consideration of the screen state and the screen area of the touch screen.

Next, as described above, if at least two or more input strokes are received and at least two or more feature data for each of them are collected, the electronic device determines that the electronic device is based on the collected at least two feature data. The control operation to be performed by the device is determined (S110).

This compares, for example, the template feature database stored in advance with the collected feature data, retrieves template feature data that is identical to the feature data collected in step S100 from the prestored template feature database, and searches the retrieved template feature data. The control operation may be determined as a control operation to be performed by the electronic device. The template feature database includes at least one template feature data, each template feature data consisting of feature data and predetermined control actions corresponding to the feature data. Since the present invention is based on at least two input strokes and feature data, as described above, each template feature data consists of a set of two or more feature data.

The template feature database that can be used in the present invention can be configured, for example, as shown in FIG.

Referring to FIG. 5, the template feature database may include an ID, a number of multi-touches, a sub-ID, feature data, a distance, an operation, and the like. The ID is an identifier for distinguishing each feature data included in the template feature database, and the number of multi-touches is a field indicating how many input strokes (feature data) the feature data is composed of. Sub-ID is an identifier provided by the number of feature data for each ID. As the feature data, the duration and interval information as described above is provided as many as the number of multi-touch, and the distance means an interval of coordinate values at which each input stroke is made. An operation is a field in which a control operation (for example, call to Kim Chul-soo and SMS to Park Young-ho) to be set corresponding to each template feature data is set.

By comparing each of the template feature data of the template feature database with the collected at least two feature data, a control operation corresponding to the input at least two input strokes is determined. In this case, however, it may be difficult to search for the template characteristic data that completely matches the collected characteristic data. Therefore, it is recommended to use a method of selecting the template characteristic data having the same range within a certain range by appropriately selecting the tolerance range. desirable. For example, when the feature data for one of the user's input strokes is input as shown in FIG. 2, the duration information is (180, 190, 185, 176) and the interval information is (200, 210, 190), and there is no template feature data that completely matches this. Most likely. Therefore, for each template feature data, it is good to determine an upper limit and a lower limit based on a predetermined range to determine whether there is characteristic data that falls within the corresponding range, that is, the same. These error ranges can be set separately for duration, interval, and distance. Meanwhile, the template feature data having the same identity may be retrieved using a method such as mapping the feature data by a certain function.

Here, the distance field may be omitted as necessary. Considering the distance field is that when two or more multi-input strokes are collected, each input stroke has a coordinate value within a range, as shown in Fig. 4, so that the average of these respective coordinate values is calculated and the distance between the average values is calculated. This can be done. Considering the distance field has a disadvantage in that a large amount of calculation is required. However, since a more precise control operation can be input, the distance field is preferably used when a high level of security is required.

Meanwhile, the step S110 may be configured to determine a control operation to be performed by the electronic device by considering not only the collected at least two feature data but also position information on a point where the input stroke contacts the touch screen. For example, assuming that the touch screen is divided into four, even if the characteristic data of at least two or more input strokes input from the user are the same, depending on whether the at least two or more input strokes are made of the first quadrant, the second quadrant, or the like. It may be configured to perform different control operations. Further, for example, in the case of two input strokes, one input stroke may be made in the first quadrant, and the other input stroke may be configured to perform a specific control operation when the second quadrant is made. In this configuration, a plurality of control operations can be set for the same multi-touch input stroke according to the position at which the multi-touch input stroke is made. Therefore, the user does not need to create and memorize several different input stroke patterns. There is an advantage. Of course, in this case the template database would have to be configured to contain positional information for each touch input stroke.

As such, when the control operation is determined through the step S110, the electronic device performs the determined control operation (S120). In this case, before performing step S120, the controller may display data on the touch screen that describes the determined control operation, and display an interface on the touch screen that allows the user to select whether to perform the control operation. You may. For example, as shown in FIG. 5, when the control operation is "Call to Kim Chul-soo", the control operation is configured to be performed only when the user selects whether or not to make a call by displaying the name and phone number Kim Chul-soo on the screen. You may.

In the above, the present invention has been described with reference to preferred embodiments of the present invention, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications from these descriptions. And variations will be possible. Therefore, the present invention should be construed with reference to the overall description of the appended claims and drawings, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 is a flowchart illustrating an embodiment of a method for controlling an operation of an electronic device based on multi-touch input based stroke feature data according to the present invention.

2 and 3 are diagrams showing an example of the configuration of feature data.

4 is a diagram for describing a phenomenon in which the multi-touch input strokes are spaced at regular intervals.

5 is a diagram illustrating an example of a configuration of a template feature database.

Claims (6)

In an electronic device having a touch screen, a method of controlling the operation of the electronic device by multi-touch input based stroke feature data, A first step of collecting at least two feature data for each of the at least two input strokes while receiving at least two input strokes comprising at least one touch input signal input through a touch of a touch screen of an electronic device; Determining a control operation to be performed in the electronic device based on the collected at least two feature data; And Third step of performing the determined control operation And controlling the operation of the electronic device according to the multi-touch input based stroke feature data. The method of claim 1, Each of the at least two feature data in the first step is divided based on the position at which the touch input signal is made. The method of controlling the operation of the electronic device according to the multi-touch input based stroke feature data. The method of claim 1, Each of the at least two feature data in the first step may include interval information, which is time interval information between respective touch input signals, and duration, which is time information when each touch input signal contacts the touch screen. A method of controlling the operation of an electronic device according to multi-touch input based stroke feature data, characterized in that at least one of the information or a combination thereof. The method of claim 1, And wherein the first step is performed only in a screen state of a predetermined touch screen and / or in a predetermined screen area of the touch screen. The method of claim 1, And said second step is performed based on each of said at least two or more feature data or combination information thereof. The method of claim 5, The second step may be performed by comparing a template feature database stored in advance with each of the collected at least two feature data or combination information thereof, respectively, or each of the at least two feature data collected from a prestored template feature database. Step 2-1 of retrieving template feature data having the same identity as the association information; And Step 2-2 of determining the control operation set according to the retrieved template feature data as the control operation to be performed by the electronic device. And controlling the operation of the electronic device according to the multi-touch input based stroke feature data.

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