KR101203701B1 - Touch information processing device of the touchscreen device and a method thereof - Google Patents

Abstract

And a database storing input conversion information, which is input information of a keyboard or a mouse, corresponding to predefined coordinate change information or rotation information of an accelerometer, and receiving a plurality of touch information from a touch screen device, Disclosed are a touch information processing apparatus and method for converting into input. The touch gesture analysis unit receives the coordinate data, calculates and outputs the change in the X and Y axes of the coordinate data, respectively, and the search unit changes information and / or the rotation information in the X and Y axes. The input conversion information stored in the database is compared to determine a current input gesture, and the associator processing unit processes an output corresponding to the input gesture as an input of the keyboard or a mouse. In this way, various keyboard or mouse inputs can be processed by changing touch coordinate information or changing acceleration meter information without using a keyboard or mouse.

Description

Touch information processing device of the touchscreen device and a method

The present invention relates to a touch screen device, and more particularly, to an apparatus and method for processing touch information of a touch screen device using infrared light.

In general, touch input devices are widely used in small electronic devices to large display devices.

It is also spreading around banks' ATMs and education.

However, most touch input devices are expensive to implement the touch input device as a capacitive type or a pressure type. In particular, as the size of the display increases, the manufacturing cost increases.

On the other hand, the input from the touch device is limited to selecting the displayed information, and various touch information processing is required to replace the keyboard or the mouse.

The technical problem to be solved by the present invention is to solve the conventional problems, touch input is possible at a low cost by using an infrared method, touch information processing of the touch screen device that can input a variety of information in place of the keyboard or mouse It is to provide an apparatus and method.

Touch information processing device of the touch screen device according to a feature of the present invention for solving the above problems,

A touch information processing device for receiving a plurality of touch information from the touch screen device and converts it into input of the input device,

A database storing input conversion information which is input information of a keyboard or a mouse corresponding to change information of a predefined coordinate;

A coordinate data receiver configured to receive the touch information and output coordinate information included in the touch information;

A touch gesture analysis unit which receives the coordinate data and calculates and outputs a change in the X and Y axes of the coordinate data, respectively;

A search unit for comparing the change information of the coordinate data on the X and Y axes with the input conversion information stored in the database to determine a current input gesture;

And an associating device processor configured to process an output corresponding to the input gesture as an input of the keyboard or a mouse.

Touch information processing device of the touch screen device according to another aspect of the present invention for solving the above problems,

A touch information processing device for receiving a plurality of touch information from the touch screen device and converts it to the input of the input device,

A database storing input conversion information which is input information of a keyboard or a mouse corresponding to change information of a predetermined coordinate or rotation information of an acceleration meter;

A coordinate data receiver configured to receive the touch information and output coordinate information included in the touch information;

An acceleration data receiving unit receiving air speed information of the acceleration meter;

A touch gesture analysis unit which receives the coordinate data and calculates and outputs a change in the X and Y axes of the coordinate data, respectively;

A behavior analyzer for calculating and outputting rotation information from the acceleration data;

A search unit for determining a current input gesture by comparing change information of the coordinate data on the X and Y axes and / or the rotation information with the input conversion information stored in the database;

And an associating device processor configured to process an output corresponding to the input gesture as an input of the keyboard or a mouse.

The touch gesture analysis unit forms a quadrangle with two touch coordinates, obtains a horizontal and vertical length change by comparing the squares of two touch coordinates touched next, and determines a gesture according to each length change. It is done.

The touch screen device,

A first light emitting device unit formed on one side of the display unit in a horizontal direction and having a plurality of light emitting devices arranged in a horizontal direction corresponding to a horizontal length of the display unit;

A first light receiving element unit formed on the other side in the horizontal direction of the display unit and having a plurality of light receiving elements arranged in a horizontal direction corresponding to the horizontal length of the display unit;

A second light emitting device unit formed on one side of the display unit in a vertical direction and having a plurality of light emitting devices arranged in a vertical direction corresponding to the length of the display unit;

A second light receiving element unit formed on the other side in the vertical direction of the display unit and having a plurality of light receiving elements arranged in the vertical direction corresponding to the longitudinal length of the display unit;

A control unit which controls to scan the entire area of the display unit and outputs the scanned result value;

A first transmitter for driving the first light emitting device unit under the control of the controller;

A second transmitter for driving the second light emitting device unit under the control of the controller;

A first receiver driving the first light receiving element according to the control of the controller;

A second receiver driving the second light receiving element according to the control of the controller;

When the controller sequentially turns on the light emitting devices of the first light emitting device, the controller sequentially scans the light receiving devices of the first light receiving device.

The controller may sequentially scan the light emitting elements connected to the second receiver by sequentially turning on the light emitting elements connected to the second transmitter.

If necessary, further comprising a first three-axis accelerometer for detecting a change in the Z-axis direction and a second three-axis accelerometer installed a predetermined distance apart from the first three-axis accelerometer, the control unit is the first Rotation is determined from the output of the second three-axis accelerometer.

The first and second transmitters and the first and second receivers may be configured in the form of a plurality of driving modules, respectively.

Touch information processing method of the touch screen device according to another aspect of the present invention for solving the above problems,

And a database storing input conversion information, which is input information of a keyboard or a mouse, corresponding to predefined coordinate change information or rotation information of an accelerometer, and receiving a plurality of touch information from a touch screen device, As a touch information processing method for converting into an input,

Receiving, by the coordinate data receiver, the touch information and outputting coordinate information included in the touch information;

Receiving, by an acceleration data receiver, acceleration information of the acceleration meter;

Receiving, by the touch gesture analysis unit, the coordinate data, and calculating and outputting changes in the X and Y axes of the coordinate data, respectively;

A behavior analysis unit calculating and outputting rotation information from the acceleration data from the change;

Determining, by a search unit, a current input gesture by comparing change information of the coordinate data with respect to X and Y axes and / or the rotation information with input conversion information stored in the database;

And an associating device processing unit to process an output corresponding to the input gesture as an input of the keyboard or a mouse.

In an embodiment of the present invention, various keyboard or mouse inputs can be processed by changing touch coordinate information or changing acceleration meter information without using a keyboard or a mouse. In addition, when the infrared method is used, the touch input is possible at a low cost, and in particular, a large input can accurately detect the touch input and can save a lot of manufacturing costs.

1 is a block diagram of a touch screen device according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an X driver and an X receiver of FIG. 1.
3 is a waveform diagram illustrating a voltage received by one light receiving element of the X receiving unit in the structure of FIG. 2.
4 is a diagram illustrating in detail a transmitter and a receiver.
5 is a diagram illustrating an arrangement state of a transmitter and a receiver.
6 is a diagram illustrating a configuration of a touch information processing device of a touch screen device according to an embodiment of the present invention.
7 is a flowchart illustrating a touch information processing method of a touch screen device according to an exemplary embodiment of the present invention.
8 to 11 illustrate examples of a touch zester determination method of a touch information processing device of a touch screen device according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

1 is a block diagram of a touch screen device according to an embodiment of the present invention.

Referring to FIG. 1, a touch screen device according to an exemplary embodiment of the present invention is installed in a form of being combined with a display unit (not shown) for displaying information, and a scan area is a display unit.

The touch screen device is mounted in a panel form to detect a user's touch operation on a display screen on which data of the display device is displayed.

The display unit may display a screen including data output from the controller 109, an image that can be selected by a user, an icon, a menu item, and the like. In addition, the display unit may display various screens according to functions implemented by the controller 109.

The X light emitting device unit 150 is formed at one side in the horizontal direction of the display unit and includes a plurality of light emitting devices arranged in the horizontal direction corresponding to the horizontal length of the display unit. The X light receiving element unit 130 is formed on the other side in the horizontal direction of the display unit and includes a plurality of light receiving elements arranged in the horizontal direction corresponding to the horizontal length of the display unit.

The Y light emitting device unit 120 is formed on one side of the display device in the longitudinal direction, and includes a plurality of light emitting devices arranged in the vertical direction corresponding to the length of the display unit. The Y light receiving element unit 140 is formed on the other side in the vertical direction of the display unit and includes a plurality of light receiving elements arranged in the vertical direction corresponding to the vertical length of the display unit.

The X transmitter 161 drives the first light emitting device unit 150 under the control of the controller 109. The Y transmitter 163 drives the second light emitting device 120 under the control of the controller 109.

The X receiver 162 drives the first light receiving element 130 under the control of the controller. The Y receiving unit 164 drives the second light receiving element unit 140 under the control of the control unit.

The control unit 109 controls to scan the entire area of the display unit and outputs the scanned result value.

When the control unit 109 sequentially turns on the light emitting device of the light emitting device unit 150 of the X transmitter 161, the control unit 109 selects the light receiving device of the light receiving device unit 130 of the X receiver 162 corresponding thereto. Turn on sequentially to scan in the X-axis direction.

In addition, when the control unit 109 sequentially turns on the light emitting device of the light emitting device unit 120 of the Y transmitter 163, the light receiving device 140 of the Y receiver 164 corresponding thereto receives the light. The devices are sequentially turned on to scan in the Y-axis direction.

If necessary, further includes a first three-axis accelerometer 110 for detecting a change in the Z-axis direction and a second three-axis accelerometer (120) which is installed at a predetermined distance apart from the first three-axis accelerometer, The controller determines rotation from the outputs of the first and second triaxial accelerometers 110 and 111.

The X and Y transmitters 161 and 162 and the X and Y receivers 163 and 164 may each be configured in a plurality of module forms and may be integrally formed with a light emitting device. That is, one module may be configured of a plurality of light emitting devices or light receiving devices of one driving module.

Next, a method of scanning with effective infrared light in a touch screen device having such a structure will be described below with reference to FIG. 2.

2, the driving module 105 of the X transmitter 161 supplies power to the light emitting device 151 according to the control signal of the controller 109, and the light emitting device 151 outputs infrared rays.

Then, the light receiving element 131 corresponding to the infrared rays is received and amplified by the receiver signal operation amplifier 206 in the receiving module 101 of the X receiver 163.

The output signal of the receiver signal operational amplifier 206 is compared with a reference voltage by the operational amplifier 209 and output through the analog / digital converter 1208.

Here, the output voltage offset of the operational amplifier 209 may be adjusted through the digital-to-analog converter 211 under the control of the controller 109.

In fact, such a structure is installed in a matrix manner in the X-axis and Y-axis directions on the entire touch screen panel in proportion to the number of light emitting elements, and is divided into a predetermined number in each driving module for convenience of manufacturing.

And the control unit 109 calculates the position of the object from the voltage received in this process will be described with reference to FIG.

PWR generates a waveform of 212 as an output signal that controls infrared radiation. AIN is the final analog voltage signal measured at ADC 208 after being amplified. TR [0... N] is a sequential output control signal line of 0 to N arranged infrared transmitter modules. RCV [0... N] is a sequential measurement control signal line of 0 to N arranged infrared transmitter modules.

213 represents the magnitude of the infrared radiation emitted in a pulse form with time from the X transmitter light emitting element, and 214 is the first output output from the unit receiver with a voltage size corresponding to the magnitude of the infrared ray incident from the X receiver light receiving element. Voltage.

215 is an external light voltage magnitude that is increased by another infrared source (for example, sunlight) that is not emitted from the light emitting device.

First, the control unit 109 measures the magnitude of the voltage emitted and measured by the infrared radiation of the i-th infrared emitter in the section A at time t using the ADC 208 as shown in Equation 1 below.

Then, similarly in section B, the magnitude of the voltage measured in the stopped state of the radiation of the i-th placed infrared ray transmitter is measured at t + 1 hour and then measured as in Equation 2 below.

As a result

을 계산하고, 이 값은 실제 방사되는 외부에서 입사되는 적외선의 크기에 상관없이 실제 적외선 소자에서 출력된 적외선 신호의 크기가 된다.

Is calculated, and this value is the size of the infrared signal output from the actual infrared device, regardless of the size of the infrared light incident from the outside.

는 적외선 수신부의 단위 모듈에서 출력되는 최초의 출력 전압을 의미한다.
here,

Denotes the first output voltage output from the unit module of the infrared receiver.

는 DAC에 의해서 조정되는 값으로

에 Offset에 의해서 최대 출력 전압이 측정값 이상으로 증폭되는 것을 제어한다.

Is the value adjusted by the DAC.

Offset controls that the maximum output voltage is amplified above the measured value.

는 외부 간섭이 존재하더라도 외부광을 차단하는 효과를 제공하고, 이것은 복잡한 협대역 필터를 사용하는 기존의 적외선 터치에 비해 간단한 구성만으로도 외부광의 간섭을 차단할수 있다.In the C and D intervals, the signal measured by the i + 1 th (next array) is displayed. So if an object in the path obscures the infrared

It provides the effect of blocking external light even if external interference is present, which can block external light interference with a simple configuration compared to the conventional infrared touch using a complicated narrowband filter.

Referring to FIGS. 4 and 5, the light emitting device and the light receiving device are actually manufactured in a module form as follows.

As shown in FIG. 4, one X driving module and a plurality of light emitting devices are provided in one module form, and a plurality of such modules are gathered into one transmitting module. This form corresponds to both the Y originating module and the X and Y receiving modules.

These modules are arranged on the panel as shown in FIG. 5.

One module consists of a maximum of 64 unit transmitter or receiver modules. That is, the number of unit incoming / outgoing units arranged per module group is 64 units.

When the infrared touch screen device is enlarged, the number of receiving modules can be increased in order to track the position of a fast object.

The active area of the touch screen is expressed by Equation 3 below, and when N = 64 is defined as the unit call-out silence of the call-out module group, m = is the number of call-out module bacteria required, n means the remaining number less than N = 64.

The combination of the unit receiving unit and the unit receiving / receiving module group, which is a group unit combination, makes it possible to easily manufacture a touch screen suitable for the size of an arbitrary touch screen.

Next, a processing device for processing touch information of the touch screen device will be described with reference to FIG. 6, and the processing device of FIG. 6 provides coordinate information of various touch screen devices such as capacitive and pressure type as well as infrared type. I can work it.

6 is a configuration diagram of a touch information processing device of a touch screen device according to an embodiment of the present invention.

Referring to FIG. 6, the touch information processing device of the touch screen device according to the embodiment of the present invention,

A touch information processing device that receives a plurality of touch information from a touch screen device and converts it into input of an input device, comprising: a database 650, a coordinate data receiver 610, a touch gesture analyzer 620, and an acceleration data receiver 630. ), A behavior analyzer 640, a searcher 660, and an associated device processor 670.

The database 650 stores input conversion information, which is input information of a keyboard or a mouse, corresponding to change information of a predefined coordinate or rotation information of an acceleration meter, and the operator defines this in advance to relate the input device of a gesture and a gesture. Edit it and save it.

The coordinate data receiving unit 1008 receives touch information and outputs coordinate information included in the touch information. The touch information may further include time information or may consist of only coordinate information.

The acceleration data receiver 630 may further receive time information when necessary to receive the acceleration information of the acceleration meters 110 and 111.

The touch gesture analyzer 620 receives the coordinate data, calculates and outputs the change in the X and Y axes of the coordinate data, respectively.

The behavior analyzer 640 calculates and outputs rotation information from the acceleration data.

The search unit 660 compares the change information of the coordinate data on the X and Y axes and / or the rotation information with the input conversion information stored in the database 650 to determine a current input gesture.

The associating device processing unit 670 processes the output corresponding to the input gesture as the input of the keyboard or mouse.

The operation of the touch information processing device of the touch screen device will now be described with reference to FIG. 7.

First, the coordinate data receiver 610 receives touch information from the touch screen device and outputs coordinate information included in the touch information (S710).

In addition, the acceleration data receiver 630 receives the acceleration information of the acceleration meter (S730). If necessary, acceleration information or coordinate information may be input together, or one or two pieces of information may be received. This information is received in real time or periodically.

Next, the touch gesture analysis unit 620 receives the coordinate data, calculates and outputs a change in the X and Y axes of the coordinate data based on a difference between the coordinates received before a predetermined time (S720). .

In addition, the behavior analyzer 640 calculates and outputs rotation information from the acceleration data from the change (S740).

Thereafter, the search unit compares the change information on the X and Y axes of the coordinate data and / or the rotation information with the input conversion information stored in the database 650 to determine a current input gesture (S750).

Next, the associating device processing unit 670 processes the output corresponding to the input gesture as the input of the keyboard or the mouse (S760).

Then, the controller (not shown) of the apparatus such as the computer performs the same process as when the keyboard or the mouse is input, and the information is displayed on the display unit.

Through this process, various input functions of a keyboard or a mouse can be implemented as a touch screen device, and if necessary, input functions not included in a keyboard or a mouse can be implemented.

Some of these embodiments will then be described in the following procedure.

In the embodiment of the present invention, the basic decision condition when applying the touch gesture determination method is a basic square calculation. The touch gesture is based on the rectangular box by the outermost coordinates of the multiple points, including the virtual image. That is, the gesture of movement, enlargement, reduction, rotation, etc. is determined by changing the corner coordinates of the rectangle and the horizontal and vertical size of the rectangle.

8 is a diagram illustrating an example of implementing an enlarged and reduced gesture using coordinate data.

Referring to FIG. 8, 1601 is a first touch coordinate at an arbitrary time and 1602 is a first touch coordinate after an arbitrary time. 1603 is the second touch coordinate after any time and 1604 is the second touch coordinate at any time.

Then, it is defined that A (t) -A (t + 1) = SX (change in length) and B (t) -B (t + 1) = SY (change in length). In this case, the length of the width of arbitrary time is defined as A (t), the length of the width after any time is defined as A (t + 1), and the length of the width of any time is defined as A (t). If A (t + 1) is defined as the horizontal length after a certain time, the gesture corresponding to the enlargement and reduction is as follows.

Zoom if SY> 0 or SX> 0

If SY <0 or SX <0, it is determined to be reduced.

That is, if the length of the X-axis or the length of the Y-axis increases after a certain time, the touch gesture analysis unit 620 determines to enlarge, and if the length of the X-axis or the length of the Y-axis decreases after a certain time, the touch gesture analysis unit 620 Is determined to be reduced, and a corresponding keyboard or mouse function is performed.

9 is a diagram illustrating an example of a rotation gesture determination method.

Referring to FIG. 9, 1701 is a first touch coordinate at an arbitrary time, and 1702 is a first touch coordinate after an arbitrary time. 1703 is the second touch coordinate after any time and 1704 is the second touch coordinate at any time.

Here, it is calculated by the method calculated in FIG. 8, and if it is SX <0 and SY> 0 or SX> 0 and SY <0, it is determined as a rotation gesture.

That is, when the horizontal length increases and the vertical length decreases (counterclockwise rotation), or when the horizontal length decreases and the vertical length increases (clockwise rotation), the touch gesture analyzer 620 rotates with the gesture of rotation. Judging and in each case the direction of rotation is different.

These cases can also be defined differently as needed.

10 is a diagram illustrating an example of a moving gesture determination method.

Referring to FIG. 10, 1801 is a first touch coordinate at an arbitrary time and 1802 is a first touch coordinate after an arbitrary time. 1803 is the second touch coordinate after any time and 1804 is the second touch coordinate at any time.

Here, if SX = 0 and SY = 0, and the coordinate of the coordinate 1801 changes to the coordinate 1802, the touch gesture analyzer 620 determines that the gesture is a moving gesture. At this time, a slight error is allowed, and an error of several centimeters to several millimeters is allowed depending on the size of the display unit so that there is no increase or decrease.

As described above, in the embodiment of the present invention, the keyboard is formed by forming a rectangle with two touch coordinates, obtaining a length and width by comparing with a rectangle touched next time, and determining a gesture according to each length change. You can implement the input function of the mouse.

11 is an example of implementing an input function from data of a three-axis accelerometer.

Referring to FIG. 11, 1201 is a leftward rotation of a 3-axis accelerometer attached to a touch, and 1203 is a leftward rotation motion according to the motion of a touch.

In this case, 1205 is an existing keyboard up key linked to the rotational motion, 1206 is a scroll up function of the existing mouse linked to the rotational motion, and 1207 is a left rotation function of the GUI window of the GUI system.

As such, the data measured by the three-axis accelerometer (110, 111) mounted on the touch screen device is analyzed by the behavior analyzer 640, and the keyboard up key such as keyboard or mouse and scrolling the mouse by rotating the acceleration meter. Corresponding to the up function, the function can be implemented.

In addition, the functions of various input devices can be implemented by changing the touch of the accelerometer and the touch screen device.

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (9)

A touch information processing device for receiving a plurality of touch information from the touch screen device and converts it to the input of the input device,
A database storing input conversion information which is input information of a keyboard or a mouse corresponding to change information of a predefined coordinate;
A coordinate data receiver configured to receive the touch information and output coordinate information included in the touch information;
A touch gesture analysis unit which receives the coordinate data and calculates and outputs a change in the X and Y axes of the coordinate data, respectively;
A search unit for comparing the change information of the coordinate data on the X and Y axes with the input conversion information stored in the database to determine a current input gesture;
An association device processor configured to process an output corresponding to the input gesture as an input of the keyboard or a mouse;
The touch gesture analysis unit forms a rectangle with two touch coordinates, obtains a horizontal and vertical length change by comparing the squares of two touch coordinates touched next, and determines a gesture according to each length change.
The touch gesture analysis unit determines that the enlargement gesture is increased when the horizontal length change is increased or the vertical length change is increased, and when the horizontal length change is decreased or the vertical length change is decreased, the touch gesture analysis unit is determined to be a reduced gesture.
The touch gesture analysis unit judges the clockwise rotation gesture when the horizontal length change decreases and the vertical length change increases, and when the horizontal length change increases and the vertical length change decreases, the touch gesture analysis unit determines the counterclockwise rotation gesture. ,
And wherein the touch gesture analysis unit determines that the gesture is a moving gesture when only two coordinates change without a horizontal length change and a vertical length change. A touch information processing device for receiving a plurality of touch information from the touch screen device and converts it to the input of the input device,
A database storing input conversion information which is input information of a keyboard or a mouse corresponding to change information of a predetermined coordinate or rotation information of an acceleration meter;
A coordinate data receiver configured to receive the touch information and output coordinate information included in the touch information;
An acceleration data receiver configured to receive acceleration information of the accelerometer;
A touch gesture analysis unit which receives the coordinate data and calculates and outputs a change in the X and Y axes of the coordinate data, respectively;
A behavior analyzer for calculating and outputting rotation information from the acceleration data;
A search unit for comparing the change information of the coordinate data to the X and Y axes, the rotation information, and the input conversion information stored in the database to determine a current input gesture;
An association device processor configured to process an output corresponding to the input gesture as an input of the keyboard or a mouse;
The touch gesture analysis unit forms a quadrangle with two touch coordinates, obtains a horizontal and vertical length change by comparing the squares of two touch coordinates touched next, and determines a gesture according to each length change.
The touch gesture analysis unit determines that the enlargement gesture is increased when the horizontal length change is increased or the vertical length change is increased, and when the horizontal length change is decreased or the vertical length change is decreased, the touch gesture analysis unit is determined to be a reduced gesture.
The touch gesture analysis unit judges the clockwise rotation gesture when the horizontal length change decreases and the vertical length change increases, and when the horizontal length change increases and the vertical length change decreases, the touch gesture analysis unit determines the counterclockwise rotation gesture. ,
And wherein the touch gesture analysis unit determines that the gesture is a moving gesture when only two coordinates change without a horizontal length change and a vertical length change. delete delete delete delete The method according to claim 1 or 2,
The touch screen device,
A display unit for displaying information;
A first light emitting device unit formed on one side of the display unit in a horizontal direction and having a plurality of light emitting devices arranged in a horizontal direction corresponding to a horizontal length of the display unit;
A first light receiving element unit formed on the other side in the horizontal direction of the display unit and having a plurality of light receiving elements arranged in the horizontal direction corresponding to the horizontal length of the display unit;
A second light emitting device unit formed on one side of the display unit in a vertical direction and having a plurality of light emitting devices arranged in a vertical direction corresponding to the length of the display unit;
A second light receiving element unit formed on the other side in the vertical direction of the display unit and having a plurality of light receiving elements arranged in the vertical direction corresponding to the longitudinal length of the display unit;
A control unit which controls to scan the entire area of the display unit and outputs the scanned result value;
A first transmitter for driving the first light emitting device unit under the control of the controller;
A second transmitter for driving the second light emitting device unit under the control of the controller;
A first receiver driving the first light receiving element according to the control of the controller;
A second receiver driving the second light receiving element according to the control of the controller;
And the control unit sequentially scans light-emitting elements of the first light-receiving element unit by sequentially turning on the light-emitting elements of the first light-emitting element unit to scan. And a database storing input conversion information, which is input information of a keyboard or a mouse, corresponding to predefined coordinate change information or rotation information of an accelerometer, and receiving a plurality of touch information from a touch screen device, As a touch information processing method for converting into an input,
Receiving, by the coordinate data receiver, the touch information and outputting coordinate information included in the touch information;
Receiving, by an acceleration data receiver, acceleration information of the acceleration meter;
Receiving, by the touch gesture analysis unit, the coordinate data, and calculating and outputting changes in the X and Y axes of the coordinate data, respectively;
A behavior analysis unit calculating and outputting rotation information from the acceleration data from the change;
Determining, by a search unit, a current input gesture by comparing change information of the coordinate data with respect to the X and Y axes, the rotation information, and input conversion information stored in the database;
Processing, by an associated device processor, an output corresponding to the input gesture as an input of the keyboard or a mouse;
In determining the current input gesture,
The touch gesture analysis unit forms a rectangle with two touch coordinates, obtains a horizontal and vertical length change by comparing the squares of two touch coordinates touched next, and determines a gesture according to each length change.
The touch gesture analysis unit determines that the enlargement gesture is increased when the horizontal length change is increased or the vertical length change is increased, and when the horizontal length change is decreased or the vertical length change is decreased, the touch gesture analysis unit is determined to be a reduced gesture.
The touch gesture analysis unit judges the clockwise rotation gesture when the horizontal length change decreases and the vertical length change increases, and when the horizontal length change increases and the vertical length change decreases, the touch gesture analysis unit determines the counterclockwise rotation gesture. ,
And wherein the touch gesture analysis unit determines the movement gesture when only two coordinates are changed without a horizontal length change and a vertical length change. delete

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