KR102372803B1 - Two-way touch-screen apparatus and method for display information using the apparatus - Google Patents

Abstract

The present invention proposes an interactive touch screen device for generating and sharing touch information as coordinate data and a method for displaying information using the same. An apparatus according to the present invention includes: a coordinate data acquisition unit configured to acquire coordinate data of a first touch by recognizing a first touch input to a first touch panel of a magnetic terminal; When the coordinate data of the second touch input to the second touch panel of at least one other terminal is obtained, the coordinate data of the second touch is based on the information on the resolution of the first touch panel and the information on the resolution of the second touch panel a coordinate data conversion unit that transforms and an image data processing unit that processes image data output from the magnetic terminal based on at least one of the coordinate data of the first touch and the coordinate data of the second touch.

Description

Two-way touch-screen apparatus and method for displaying information using same

The present invention relates to a touch screen device and a method for displaying information using the same. More particularly, it relates to a touch screen device that shares touch information with other devices, and a method for displaying information using the same.

A two-way touch system refers to a system in which two or more different terminals share image information and touch information. A conventional two-way touch system operates by including touch information in image data to share the image data.

However, since the size of the image data itself is very large, it takes a lot of time for one terminal to transmit the image data to the other terminal, and thus there is a problem in that a data transmission delay phenomenon occurs. In addition, there is a problem in that a lag phenomenon occurs due to traffic when the communication state between different terminals is poor.

Korea Patent Publication No. 2013-0028504 (published date: 2013.03.19.)

The present invention has been devised to solve the above problems, and an object of the present invention is to propose a bidirectional touch screen device for generating and sharing touch information as coordinate data and a method for displaying information using the same.

However, the object of the present invention is not limited to the above, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention has been devised to achieve the above object, comprising: a coordinate data acquisition unit for recognizing a first touch input to a first touch panel of a magnetic terminal and acquiring coordinate data of the first touch; When coordinate data of a second touch input to a second touch panel of at least one other terminal is obtained, the second touch based on the information on the resolution of the first touch panel and the information on the resolution of the second touch panel a coordinate data conversion unit that transforms the coordinate data of ; and an image data processing unit configured to process the image data output from the magnetic terminal based on at least one of the coordinate data of the first touch and the coordinate data of the second touch. suggest

Preferably, the interactive touch screen device further includes a coordinate data transmission controller configured to transmit the coordinate data of the first touch to the other terminal in real time when the coordinate data of the first touch is obtained.

Preferably, the coordinate data conversion unit also acquires information on the resolution of the second touch panel when acquiring the coordinate data of the second touch.

Preferably, the image data processing unit sequentially uses the coordinate data of the first touch and the coordinate data of the second touch based on the time at which the first touch is sensed and the time at which the second touch is sensed. Process image data.

Preferably, the interactive touch screen device further comprises a terminal state determination unit for determining whether the magnetic terminal is a first terminal that senses a touch signal every predetermined time or a second terminal that does not sense the touch signal, The coordinate data obtaining unit does not operate when it is determined that the own terminal is the second terminal.

Preferably, the interactive touch screen device further comprises a processing speed determining unit for determining whether data processing speeds of at least two other terminals are equal to or greater than the data processing speed of the own terminal, and data processing of the at least two other terminals If it is determined that the speeds are equal to or higher than the data processing speed of the own terminal, the coordinate data transmission control unit simultaneously transmits the coordinate data of the first touch to the at least two other terminals, and at least one of the at least two other terminals If it is determined that the data processing speed of the terminal is less than the data processing speed of the own terminal, the coordinate data transmission control unit sequentially transmits the coordinate data of the first touch to the at least two other terminals whenever the coordinate data of the first touch is obtained.

Preferably, the interactive touch screen device further comprises a reception order determining unit that determines a reception order of the coordinate data of the at least two other terminals based on a distance between the own terminal and each other terminal, and the coordinate data transmission control unit Sequentially transmits to the at least two other terminals based on the coordinate data reception order.

Preferably, the two-way touch screen device grants access authority to connect the own terminal and the other terminal to communication based on the information on the other terminal provided to the own terminal when the own terminal and the other terminal are firstly communicatively connected It further includes, wherein the coordinate data conversion unit acquires the coordinate data of the second touch with respect to the other terminal communicatively connected to the magnetic terminal.

The present invention also provides a coordinate data acquisition step of recognizing a first touch input to a first touch panel of a magnetic terminal and acquiring coordinate data of the first touch; When coordinate data of a second touch input to a second touch panel of at least one other terminal is obtained, the second touch based on the information on the resolution of the first touch panel and the information on the resolution of the second touch panel a coordinate data transformation step of transforming the coordinate data of ; and an image data processing step of processing the image data output from the magnetic terminal based on at least one of the coordinate data of the first touch and the coordinate data of the second touch. A method for displaying information on a device is proposed.

Preferably, between the step of obtaining the coordinate data and the step of converting the coordinate data, when the coordinate data of the first touch is obtained, a coordinate data transmission control step of transmitting the coordinate data of the first touch to the other terminal in real time include more

Preferably, in the step of converting the coordinate data, information on the resolution of the second touch panel is also acquired when the coordinate data of the second touch is acquired.

Preferably, the image data processing step sequentially uses the coordinate data of the first touch and the coordinate data of the second touch based on the time at which the first touch is sensed and the time at which the second touch is sensed. The image data is processed.

Preferably, before the step of obtaining the coordinate data, a terminal state determination step of determining whether the magnetic terminal is a first terminal sensing a touch signal or a second terminal not sensing the touch signal at every predetermined time is further performed Including, the step of obtaining the coordinate data does not work when it is determined that the own terminal is the second terminal.

Preferably, between the coordinate data acquisition step and the coordinate data transmission control step, the method further comprises a processing speed determination step of determining whether the data processing speeds of at least two other terminals are equal to or greater than the data processing speed of the own terminal, , when it is determined that the data processing rates of the at least two other terminals are equal to or greater than the data processing speed of the own terminal, the coordinate data transmission control step simultaneously transmits the coordinate data of the first touch to the at least two other terminals, , when it is determined that the data processing speed of at least one terminal among the at least two other terminals is less than the data processing speed of the own terminal, the coordinate data transmission control step is performed whenever the coordinate data of the first touch is obtained. It is sequentially transmitted to at least two other terminals.

Preferably, between the step of determining the processing speed and the step of controlling the coordinate data transmission, a reception order determination step of determining the coordinate data reception order of the at least two other terminals based on a distance between the own terminal and each other terminal The method further includes, wherein the coordinate data transmission control step sequentially transmits the coordinate data to the at least two other terminals based on the coordinate data reception order.

Preferably, between the step of obtaining the coordinate data and the step of converting the coordinate data, based on information about the other terminal provided to the own terminal when the own terminal and the other terminal are firstly connected to each other, the self terminal and the other terminal The method further includes a step of granting access authority to connect the terminal to communication, wherein the step of converting the coordinate data acquires the coordinate data of the second touch with respect to the other terminal that is connected in communication with the own terminal.

The present invention can obtain the following effects through the configurations for achieving the above object.

First, since the touch information is generated as coordinate data rather than image data, the size of the data itself can be reduced, and accordingly, the time taken to transmit the touch information to another terminal can also be reduced.

Second, even if a plurality of terminals share touch information, a data transmission delay phenomenon can be prevented, and even if a communication state is poor, a lag phenomenon due to traffic can be minimized by reducing the data transmission amount.

Third, since touch information is shared between different terminals, it is possible to provide the convenience of allowing a large number of people to work simultaneously on one screen.

1 is a conceptual diagram of a display system according to an embodiment of the present invention.
2 is a detailed view of a display system according to an embodiment of the present invention.
3 is a first reference diagram for explaining a method of sharing touch information between two different terminals in a display system according to an embodiment of the present invention.
4 is a second reference diagram for explaining a method of sharing touch information between two different terminals in a display system according to an embodiment of the present invention.
5 is a flowchart illustrating an operation in both directions in a display system according to an embodiment of the present invention.
6 is a flowchart illustrating a unidirectional operation in a display system according to an embodiment of the present invention.
7 is a reference diagram for explaining a method of processing touch information in a non-real time in a display system according to an embodiment of the present invention.
8 is a reference diagram for explaining a method of processing touch information in real time in a display system according to an embodiment of the present invention.
9 is a conceptual diagram schematically illustrating an interactive touch screen device according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, it should be noted that in adding reference numerals to the components of each drawing, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, preferred embodiments of the present invention will be described below, but the technical spirit of the present invention is not limited thereto and may be variously implemented by those skilled in the art without being limited thereto.

The present invention relates to a two-way touch screen device equipped with a touch module capable of two-way communication and a method for displaying information using the same. Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a conceptual diagram of a display system according to an embodiment of the present invention.

The display system 100 proposed by the present invention is a display system composed of terminals equipped with a two-way touch interface, and uses the display terminals 110, 120, 130, 140, and 150 equipped with a touch panel as a single display terminal. It is a system that provides a solution that can be used by a large number of people.

The display terminals 110 , 120 , 130 , 140 , and 150 are interconnected wired and wirelessly through Wireless Display (WiDi), Mobile High-Definition Link (MHL), Bluetooth, USB, etc., and touch information and image information share etc. The display terminals 110 , 120 , 130 , 140 , and 150 operate by bidirectionally communicating touch information as coordinate data rather than image data.

2 is a detailed view of a display system according to an embodiment of the present invention.

The display system 100 proposed by the present invention includes a plurality of display terminals such as a first display terminal 210 , a second display terminal 220 , a third display terminal 230 , and a fourth display terminal 240 . .

In the example of FIG. 2 , four terminals are presented as display terminals included in the display system 100 , but the number of display terminals included in the display system 100 is not limited thereto in the present invention.

The first display terminal 210 is a terminal serving as a master in the display system 100 , and includes a first display panel 211 , a first touch panel 212 , and a first image I/F 213 . , a first touch I/F 214 , a first touch C/B 215 , and the like. In the present invention, the first display terminal 210 is set as a terminal in charge of the master role, but in this embodiment, only the first display terminal 210 plays the master role.

The first display panel 211 outputs image data and the like from the first display terminal 210 . The first display panel 211 may share image information with the second display terminal 220 , the third display terminal 230 , and the fourth display terminal 240 through the first image I/F 214 . there is.

The first touch panel 212 receives touch information from the first display terminal 210 . The first touch panel 212 is the second display terminal 220 , the third display terminal 230 , and the fourth display through the first touch I/F 214 , the first touch C/B 215 , and the like. It is possible to share touch information with the terminal 240 and the like.

The first image I/F 213 performs an interface function, and functions to interconnect the first display panel 211 with other display terminals 220 , 230 , and 240 to enable sharing of image information. carry out

The first touch I/F 214 performs an interface function, and functions to interconnect the first touch panel 212 with other display terminals 220 , 230 , and 240 to enable sharing of touch information. carry out

When a user's touch is input to the first touch panel 212 , the first touch C/B 215 performs a function of acquiring coordinate data related to the touch as touch information. To this end, the first touch C/B 215 may include a controller board and an OS board connected to the first touch panel 212 to drive the touch. In the present invention, the touch information acquired by the first touch C/B 215 can be shared with other display terminals 220 , 230 , and 240 through the first touch I/F 214 .

The second display terminal 220 is a terminal serving as a slave in the display system 100 , and includes a second display panel 221 , a second touch panel 222 , and a second image I/F 223 . , a second touch I/F 224 , a second touch C/B 225 , and the like. In the present invention, the display system 100 is composed of a terminal in charge of one master role and a plurality of terminals in charge of a plurality of slave roles, but it is also possible that there are two or more terminals in charge of the master role.

The second display panel 221 has the same concept as the first display panel 211 in the second display terminal 220 .

The second touch panel 222 has the same concept as the first touch panel 212 in the second display terminal 220 .

The second image I/F 223 has the same concept as the first image I/F 213 in the second display terminal 220 .

The second touch I/F 224 has the same concept as the first touch I/F 214 in the second display terminal 220 .

The second touch C/B 225 has the same concept as the first touch C/B 215 in the second display terminal 220 .

The third display terminal 230 and the fourth display terminal 240 are terminals that serve as slaves in the display system 100 together with the second display terminal 220 . The third display panel 231 , the third touch panel 232 , the third image I/F 233 , the third touch I/F 234 , and the third touch C included in the third display terminal 230 . The fourth display panel 241, the fourth touch panel 242, the fourth image I/F 243, and the fourth touch I/F 244 included in the /B 235, etc., the fourth display terminal 240 ), a second display panel 221 , a second touch panel 222 , a second image I/F 223 , and a second The first display panel 211, the first touch panel 212, the first image I/ The F 213 , the first touch I/F 214 , and the first touch C/B 215 have the same concept.

The internal structure of the display system 100 has been described above with reference to FIGS. 1 and 2 . Hereinafter, a method of sharing touch information between two different terminals in the display system 100 will be described.

3 is a first reference diagram for explaining a method of sharing touch information between two different terminals in a display system according to an embodiment of the present invention. 4 is a second reference diagram for explaining a method of sharing touch information between two different terminals in a display system according to an embodiment of the present invention.

In this embodiment, a method of sharing touch information between the first display terminal 210 serving as the master and the second display terminal 220 serving as the slave will be described with reference to FIGS. 3 and 4 . , of course, touch information may be shared between the third display terminal 230 and the fourth display terminal 240 serving as slaves in the same way.

First, a hardware structure will be described with reference to FIG. 3 .

The first touch C/B 215 includes a first touch controller 311 and a first MCU 312 .

The first touch controller 311 performs a function of driving the first touch panel 212 positioned on the first display panel 211 as a touch sensor under the control of the first MCU 312 .

The first MCU 312 controls the first touch controller 311 to obtain touch information input to the first touch panel 212 . When a touch is input on the first touch panel 212 , the first MCU 312 obtains coordinate data of the touch as touch information. The first MCU 312 may be implemented in the form of a Field Programmable Gate Array (FPGA) in the present invention.

The first controller 320 performs a function of reflecting the touch information acquired by the first MCU 312 to the image data output by the first display panel 211 . In addition, the first control unit 320 transmits the touch information acquired by the first MCU 312 to the second control unit 340 so that it can be equally reflected in the image data output by the second display panel 221 . do.

The first control unit 320 also performs a function of receiving the touch information acquired by the second MCU 332 through the second control unit 340 and reflecting it on the image data output by the first display panel 211 . .

The first control unit 320 is communicatively connected to the second control unit 340 through a wired/wireless communication network. In the present invention, the wired/wireless communication network connecting the first control unit 320 and the second control unit 340 for communication includes an intranet, the Internet, a Bluetooth, a WiFi, and a wire. . The first control unit 320 and the second control unit 340 may be implemented in the form of a main controller such as a computer or a smart phone in the present invention.

The second touch C/B 225 includes a second touch controller 331 and a second MCU 332 . In the present invention, the second touch controller 331 and the second MCU 332 may be implemented with the same concept as the first touch controller 311 and the first MCU 312 . Of course, the second control unit 340 may also be implemented with the same concept as the first control unit 320 .

Next, the software structure will be described with reference to FIG. 4 .

The first touch driver 410 is a module executed by the first MCU 312 , and includes a touch coordinate converting unit 411 and a touch coordinate recognizing unit 412 .

The touch coordinate recognition unit 412 performs a function of recognizing a touch input to the first touch panel 212 and acquiring coordinate data of the touch as touch information. Also, the touch coordinate recognition unit 412 performs a function of transmitting the acquired touch information to the other terminals 220 , 230 , and 240 through the first touch I/F 214 .

When touch information is acquired by other terminals 220 , 230 , and 240 , the touch coordinate converter 411 performs a function of acquiring the touch information through the first touch I/F 214 . In addition, the touch coordinate converter 411 performs a function of converting the coordinate data included in the acquired touch information to suit the resolution of the first display panel 211 .

When the display terminals 210 , 220 , 230 , and 240 are communicatively connected to each other to share image information, the touch panels 212 , 222 , 232 provided in the display terminals 210 , 220 , 230 , and 240 . , 242) may also be shared.

For example, when touch information is received from the second display terminal 220 , the touch coordinate converting unit 411 provides information on the resolution of the first touch panel 212 and information on the resolution of the second touch panel 222 . Based on the coordinate data received from the second display terminal 220 may be converted to suit the first display terminal 210 .

Meanwhile, in the present invention, when transmitting touch information to another terminal, it is also possible to transmit the touch information by including information on the resolution of the touch panel (or information on the resolution of the display panel).

The OS platform 420 and the application layer 430 are modules executed by the first controller 320 . The OS platform 420 is related to the operating system of the first control unit 320 , and the application layer 430 is related to the application program of the first control unit 320 . The OS platform 420 and the application layer 430 first display the touch information of the own terminal obtained by the touch coordinate recognition unit 412 , the touch information of another terminal converted by the touch coordinate conversion unit 411 , and the like. A function of reflecting the image data output by the panel 211 is performed.

The second touch driver 440 is a module performed by the second MCU 332 provided in the second display terminal 220 and performs the same function as the first touch driver 410 in the present invention.

The touch information sharing method proposed by the present invention has been described with reference to FIGS. 3 and 4 above. The method proposed by the present invention is summarized as follows.

(1) When touch information is acquired by the own terminal

The touch information is reflected in the image data output by the own terminal and transmitted to other terminals through the interface.

(2) When touch information is acquired by another terminal

After the touch information received from the other terminal is converted to coordinate data suitable for the touch panel of the terminal, the coordinate data is reflected in the image data output by the terminal.

Next, when the first display terminal 210 serving as the master and the second display terminal 220 serving as the slave both acquire touch information in the display system 100 according to an embodiment of the present invention ( Bidirectional operation) and a case in which only the first display terminal 210 obtains touch information (unidirectional operation) will be described. Hereinafter, the bidirectional operation and the unidirectional operation will be described with respect to one display terminal serving as the master and one display terminal serving as the slave. The same may be applied to the display terminal and a plurality of display terminals serving as slaves.

In addition, as described above, the bidirectional operation and the unidirectional operation may be applied between the third display terminal 230 and the fourth display terminal 240 serving as slaves.

FIG. 5 is a flowchart illustrating bidirectional operation in the display system according to an embodiment of the present invention, and FIG. 6 is a flowchart illustrating unidirectional operation in the display system according to an embodiment of the present invention.

First, a bidirectional operation will be described with reference to FIG. 5 .

The first touch controller 311 of the first display terminal 210 senses a first touch signal input to the first touch panel 212 under the control of the first MCU 312 (touch signal sensing; S510). .

Thereafter, the first MCU 312 of the first display terminal 210 generates coordinate data of a portion where the first touch signal is sensed in the first touch panel 212 as first touch information (touch coordinate recognition; S520 ). . This function of the first MCU 312 may be performed by the touch coordinate recognition unit 412 of the first touch driver 410 .

Thereafter, the first control unit 320 reflects the first touch information to the image data output through the first display panel 211 ( S530 ).

Meanwhile, when the second touch controller 331 of the second display terminal 220 senses the second touch signal input to the second touch panel 222 , the first touch I/F ( In step 214, a second touch signal is acquired through a wired/wireless communication network (S540).

Thereafter, the first MCU 312 of the first display terminal 210 senses the second touch signal based on the information on the resolution of the second touch panel 222 and the information on the resolution of the first touch panel 212 . The coordinate data of the converted portion is converted to be appropriate for the first touch panel 212 and generated as second touch information (touch coordinate transformation; S550).

For example, if the resolution of the first touch panel 212 is 2 * 2, the resolution of the second touch panel 222 is 4 * 4, and the coordinate data of the portion where the second touch signal is sensed is (2, 2), the 1 MCU 312 converts this coordinate data into (1, 1) suitable for the first touch panel 212 to generate the second touch information. This function of the first MCU 312 may be performed by the touch coordinate converting unit 411 of the first touch driver 410 .

Thereafter, the first control unit 320 reflects the second touch information to the image data output through the first display panel 211 (S560).

Meanwhile, in order for the first MCU 312 of the first display terminal 210 to reflect the first touch information and the second touch information in the image data output through the first display panel 211 according to the time sequence, When generating the first touch information and the second touch information, it is also possible to include a time at which the first touch signal is sensed and a time at which the second touch signal is sensed, respectively.

Meanwhile, when the first touch signal is sensed by the first touch controller 311 , the first MCU 312 of the first display terminal 210 transmits the first touch signal to the second through the first touch I/F 214 . It is of course transmitted to the display terminal 220 .

Meanwhile, in the example of FIG. 5 , the second display terminal 220 operates in the same manner as the first display terminal 210 , and includes the first touch information and the second touch information on the image data output through the second display panel 221 . is reflected in the same form as that of the first display terminal 210 . Since the operation process of the first display terminal 210 is equally applied to the second display terminal 220, a detailed description thereof will be omitted herein.

Next, the unidirectional operation will be described with reference to FIG. 6 .

In the case of a one-way operation, only the first display terminal 210 senses the touch signal, and the second display terminal 220 does not sense the touch signal. Therefore, unlike the case of the interactive operation, the operation process of the first display terminal 210 and the operation process of the second display terminal are different from each other.

Hereinafter, an operation process of the first display terminal 210 will be first described with reference to FIG. 6A , and then an operation process of the second display terminal 220 will be described with reference to FIG. 6B .

First, referring to FIG. 6A , the first touch controller 311 of the first display terminal 210 receives a first touch input to the first touch panel 212 under the control of the first MCU 312 . A signal is sensed (touch signal sensing; S610).

Thereafter, the first MCU 312 of the first display terminal 210 generates coordinate data of a portion where the first touch signal is sensed in the first touch panel 212 as first touch information (touch coordinate recognition; S620 ). .

Thereafter, the first control unit 320 reflects the first touch information to the image data output through the first display panel 211 (S630).

Meanwhile, when the first touch signal is sensed by the first touch controller 311 , the first MCU 312 of the first display terminal 210 transmits the first touch signal to the second through the first touch I/F 214 . It is transmitted to the display terminal 220 (S640).

Next, referring to FIG. 6B , when the first touch controller 311 of the first display terminal 210 senses the first touch signal input to the first touch panel 212 , the second display terminal The second touch I/F 224 of 220 acquires a first touch signal through a wired/wireless communication network (S610').

Thereafter, the second MCU 332 of the second display terminal 220 senses the first touch signal based on the information on the resolution of the first touch panel 212 and the information on the resolution of the second touch panel 222 . The coordinate data of the converted portion is converted to be suitable for the second touch panel 222 and generated as first touch information (touch coordinate transformation; S620').

Thereafter, the second control unit 340 reflects the first touch information to the image data output through the second display panel 221 ( S630 ′).

Next, one display terminal (first display terminal 210) serving as a master and a plurality of display terminals (second display terminal 220, third display terminal 230, and a fourth) serving as slaves A method in which the display terminal 240, ...) reflects the coordinate data generated by the touch information to the image data will be described.

In the following embodiment, one display terminal (first display terminal 210) serving as a master and three display terminals (second display terminal 220, third display terminal 230) serving as slaves , a method in which the fourth display terminal 240 reflects the coordinate data to the image data will be described, but the number of terminals serving as a master and the number of terminals serving as a slave are not limited thereto.

7 is a reference diagram for explaining a method of processing touch information in real time in a display system according to an embodiment of the present invention, and FIG. 8 is a non-real time view of touch information in the display system according to an embodiment of the present invention It is a reference diagram for explaining the processing method.

First, a touch information real-time processing method will be described with reference to FIG. 7 .

The first display terminal 210 performs coordinates 0, coordinates 1, coordinates 2, ... according to sensing of touch signals. When coordinate data such as , coordinate n are obtained, the first image data 710 is generated by reflecting the image data output by the first display panel 211 as touch information.

The coordinate data obtained according to the sensing of the touch signals are shared with the second display terminal 220, the third display terminal 230, the fourth display terminal 240, etc. through a wired/wireless communication network to the second display terminal 220, The third display terminal 230 and the fourth display terminal 240 are also displayed as touch information on image data output by the second display panel 221 , the third display panel 231 , the fourth display panel 241 , and the like. In reflection, the second image data 720 , the third image data 730 , the fourth image data 740 , and the like are generated.

However, if the processing speed of the second display terminal 220 , the third display terminal 230 , and the fourth display terminal 240 does not reach the processing speed of the first display terminal 210 , the touch information real-time processing described with reference to FIG. 7 . The method is difficult to implement.

In the present invention, it is also possible to process touch information in non-real time in consideration of this point. Hereinafter, a method for non-real time processing of touch information will be described with reference to FIG. 8 .

The first display terminal 210 obtains information on the processing speed from the second display terminal 220 , the third display terminal 230 , the fourth display terminal 240 , and the like before sharing the coordinate data.

Information on the processing speed of the second display terminal 220 , the third display terminal 230 , and the fourth display terminal 240 is the second display terminal 220 , the third display terminal 230 , and the fourth display. When the terminal 240 and the like are communicatively connected to the first display terminal 210 , it is provided to the first display terminal 210 , or the second display terminal 220 , the third display terminal 230 , and the fourth display terminal 240 . ) and the like may be provided to the first display terminal 210 when registered in the first display terminal 210 .

When information on the processing speed of the second display terminal 220 , the third display terminal 230 , the fourth display terminal 240 is obtained, the first display terminal 210 displays its own processing speed and the second display terminal 210 . The second display terminal 220 , the third display terminal 230 , and the fourth display terminal 240 by comparing the processing speeds of the terminal 220 , the third display terminal 230 , and the fourth display terminal 240 . It is determined whether the processing speed of the etc. is equal to or greater than its own processing speed.

When it is determined that the processing speed of the second display terminal 220 , the third display terminal 230 , the fourth display terminal 240 is higher than or equal to the processing speed of the first display terminal 210 , the display system ( In 100), touch information is processed according to the method of FIG. 7 .

On the other hand, if it is determined that the processing speed of at least one terminal among the second display terminal 220 , the third display terminal 230 , and the fourth display terminal 240 is less than the processing speed of the first display terminal 210 , the In the display system 100 according to the present invention, touch information is processed according to the method of FIG. 8 .

On the other hand, in the present invention, the second display terminal 220 , the third display terminal 230 , the fourth display terminal 240 , etc. are previously set to be communicatively connected to the first display terminal 210 through a registration process in advance. possible.

For example, by implementing a two-way interface using wired and wireless communication networks such as WiFi, Bluetooth, TCP-IP, UDP, USB, etc. there is. In this case, there is also an advantage in that there is no need to register a separate pin number when reconnecting between terminals once connected.

According to FIG. 8 , the touch information non-real time processing method is operated according to the following sequence.

The first display terminal 210 performs coordinates 0, coordinates 1, coordinates 2, ... according to sensing of touch signals. When coordinate data such as , coordinate n are obtained, the first image data 710 is generated by reflecting the image data output by the first display panel 211 as touch information.

In addition, the first display terminal 210 sequentially transmits the coordinate data to the second display terminal 220, the third display terminal 230, the fourth display terminal 240, etc. according to a predetermined order when the coordinate data is obtained. .

For example, when the coordinate data is obtained in the order of coordinate 0, coordinate 1, coordinate 2, etc. and the order of receiving the coordinate data is the second display terminal 220, the third display terminal 230, the fourth display terminal 240, etc. , the first display terminal 210 transmits coordinate 0 to the second display terminal 220 , and then transmits coordinates 1 and 2 to the third display terminal 230 and the fourth display terminal 240 , respectively.

When the second display terminal 220, the third display terminal 230, the fourth display terminal 240, etc. receive coordinate data from the first display terminal 210, the second 'image data ( 720'), third' image data 730', and fourth' image data 740' are generated.

Conventionally, since touch information is transmitted as image data, there is a problem in that it is impossible to connect unless a high-spec system is used due to a large amount of data to be transmitted. In addition, there was a problem in that communication delay occurred due to the occurrence of data traffic. In addition, as the number of people accessing the system increases, the amount of data increases exponentially, resulting in more severe traffic.

Since the system proposed in the present invention transmits only coordinate data, there is an advantage in that the amount of data is not large even if a large number of people access it. In addition, as a plurality of people use a plurality of touch screen displays like one touch screen display, it is possible to provide the convenience of being able to work on one screen at the same time.

The present invention described above can be applied to a smart school electronic blackboard, a business video conferencing system, a DID device using big data, and the like. It can be applied to all display devices employing a touch panel, etc.

An embodiment of the present invention has been described above with reference to FIGS. 1 to 8 . Hereinafter, a preferred embodiment of the present invention that can be inferred from such an embodiment will be described.

9 is a conceptual diagram schematically illustrating an interactive touch screen device according to a preferred embodiment of the present invention.

Referring to FIG. 9 , the interactive touch screen device 900 according to the preferred embodiment of the present invention includes a coordinate data acquisition unit 910 , a coordinate data conversion unit 920 , an image data processing unit 930 , a power supply unit 940 , and a main control unit. part 950 .

The power supply unit 940 performs a function of supplying power to each component constituting the interactive touch screen device 900 .

The main control unit 950 performs a function of controlling the overall operation of each component constituting the interactive touch screen device 900 .

The coordinate data acquisition unit 910 performs a function of acquiring coordinate data of the first touch by recognizing the first touch input to the first touch panel of the terminal. The coordinate data acquisition unit 910 is a concept corresponding to the touch coordinate recognition unit 412 .

When the coordinate data of the second touch input to the second touch panel of at least one other terminal is obtained, the coordinate data conversion unit 920 receives information on the resolution of the first touch panel and information on the resolution of the second touch panel. It performs a function of transforming the coordinate data of the second touch based on the second touch. The coordinate data conversion unit 920 is a concept corresponding to the touch coordinate conversion unit 411 .

The coordinate data converter 920 may also acquire information on the resolution of the second touch panel when acquiring the coordinate data of the second touch.

The image data processing unit 930 based on at least one of the coordinate data of the first touch acquired by the coordinate data acquiring unit 910 and the coordinate data of the second touch transformed by the coordinate data converting unit 920 . to process the image data output from the terminal. The image data processing unit 930 is a concept corresponding to the first control unit 320 .

The image data processing unit 930 may process image data by sequentially using the coordinate data of the first touch and the coordinate data of the second touch based on the time when the first touch is sensed and the time when the second touch is sensed. .

The interactive touch screen device 900 may further include a coordinate data transmission control unit 961 .

When the coordinate data of the first touch is acquired by the coordinate data acquisition unit 910 , the coordinate data transmission control unit 961 performs a function of transmitting the coordinate data of the first touch to another terminal in real time. The coordinate data transmission control unit 961 is a concept corresponding to the first touch I/F 214 and the first MCU 312 .

The interactive touch screen apparatus 900 may further include a terminal state determination unit 962 .

The terminal state determination unit 962 performs a function of determining whether the terminal is a first terminal that senses a touch signal or a second terminal that does not sense a touch signal every predetermined time.

In this case, the coordinate data acquisition unit 910 does not operate when it is determined that the own terminal is the second terminal. On the other hand, the coordinate data acquisition unit 910 operates normally when it is determined that the own terminal is the first terminal.

The interactive touch screen device 900 may further include a processing speed determiner 963 .

The processing speed determining unit 963 performs a function of determining whether the data processing speeds of at least two other terminals are equal to or greater than the data processing speed of the own terminal.

In this case, the coordinate data transmission control unit 961 may operate as follows.

First, when it is determined that the data processing rates of at least two other terminals are equal to or greater than the data processing speed of the own terminal, the coordinate data transmission control unit 961 simultaneously transmits the coordinate data of the first touch to at least two other terminals.

Second, if it is determined that the data processing speed of at least one terminal among the at least two other terminals is less than the data processing speed of the own terminal, the coordinate data transmission control unit 961 controls at least two times each time the coordinate data of the first touch is obtained. sequentially to other terminals of

The interactive touch screen device 900 may further include a reception order determining unit 964 .

The reception order determining unit 964 performs a function of determining the coordinate data reception order of at least two other terminals based on the distance between the terminal and each other terminal.

In this case, the coordinate data transmission control unit 961 sequentially transmits the coordinate data to at least two other terminals based on the reception order of the coordinate data.

The interactive touch screen device 900 may further include an access authorization unit 965 .

The access authority granting unit 965 performs a function of communicatively connecting the own terminal and the other terminal based on the information on the other terminal provided to the own terminal when the own terminal and the other terminal are first connected.

In this case, the coordinate data conversion unit 920 acquires the coordinate data of the second touch with respect to the other terminal communicatively connected to the terminal.

Next, an operation method of the interactive touch screen device 900 will be described.

First, the coordinate data obtaining unit 910 recognizes the first touch input to the first touch panel of the terminal to obtain the coordinate data of the first touch (STEP A).

Then, when the coordinate data conversion unit 920 obtains the coordinate data of the second touch input to the second touch panel of at least one other terminal, information on the resolution of the first touch panel and information on the resolution of the second touch panel Converts the coordinate data of the second touch based on (STEP B).

Thereafter, the image data processing unit 930 processes the image data output from the terminal based on at least one of the coordinate data of the first touch and the coordinate data of the second touch (STEP C).

Meanwhile, between STEP A and STEP B, when the coordinate data transmission control unit 961 obtains the coordinate data of the first touch, it may transmit the coordinate data of the first touch to another terminal in real time (STEP D). This step performed by the coordinate data transmission control unit 961 may be performed at any time as long as it is performed after STEP A.

Meanwhile, before STEP A, the terminal state determiner 962 may determine whether the terminal is a first terminal that senses a touch signal or a second terminal that does not sense a touch signal every predetermined time. In this case, the coordinate data acquisition unit 910 does not operate when the terminal state determination unit 962 determines that the own terminal is the second terminal.

Meanwhile, between STEP A and STEP D, the processing speed determining unit 963 may determine whether the data processing speeds of at least two other terminals are equal to or greater than the data processing speed of the own terminal (STEP E). In this case, if it is determined that the data processing speeds of at least two other terminals are equal to or higher than the data processing speed of the own terminal, the coordinate data transmission control unit 961 simultaneously transmits the coordinate data of the first touch to at least two other terminals. On the other hand, if it is determined that the data processing speed of at least one terminal among the at least two other terminals is less than the data processing speed of the own terminal, the coordinate data transmission control unit 961 controls at least two data processing units whenever the coordinate data of the first touch is obtained. It is sequentially transmitted to other terminals.

Meanwhile, between STEP E and STEP D, the reception order determining unit 964 may determine the coordinate data reception order of at least two other terminals based on a distance between the terminal and each other terminal. In this case, the coordinate data transmission control unit 961 may sequentially transmit the coordinate data to at least two other terminals based on the coordinate data reception order.

Meanwhile, between STEP A and STEP B, the access authority granting unit 965 may connect the own terminal to another terminal based on the information on the other terminal provided to the own terminal when the own terminal and the other terminal are first communicated. . In this case, the coordinate data conversion unit 920 acquires the coordinate data of the second touch with respect to the other terminal communicatively connected to the terminal. The above-described step of the access authority granting unit 965 may be performed at any time as long as it is performed before STEP B.

Even though all the components constituting the embodiment of the present invention described above are described as being combined or operated in combination, the present invention is not necessarily limited to this embodiment. That is, within the scope of the object of the present invention, all the components may operate by selectively combining one or more. In addition, all of the components may be implemented as one independent hardware, but a part or all of each component is selectively combined to perform some or all of the functions combined in one or a plurality of hardware program modules It may be implemented as a computer program having In addition, such a computer program is stored in a computer readable media such as a USB memory, a CD disk, a flash memory, etc., read and executed by a computer, thereby implementing the embodiment of the present invention. The recording medium of the computer program may include a magnetic recording medium, an optical recording medium, and the like.

In addition, all terms including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined in the detailed description. Terms commonly used, such as those defined in the dictionary, should be interpreted as being consistent with the contextual meaning of the related art, and are not interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications, changes and substitutions within the scope without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are for explaining, not limiting, the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments and the accompanying drawings . The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (16)

a coordinate data acquisition unit that recognizes a first touch input to a first touch panel of the magnetic terminal and acquires coordinate data of the first touch;
When the coordinate data of the second touch input to the second touch panel of at least one other terminal is obtained, the second touch based on the information on the resolution of the first touch panel and the information on the resolution of the second touch panel a coordinate data conversion unit that transforms the coordinate data of ;
an image data processing unit configured to process image data output from the magnetic terminal based on at least one of the coordinate data of the first touch and the coordinate data of the second touch; and
and a coordinate data transmission control unit configured to transmit the coordinate data of the first touch to at least two other terminals when the coordinate data of the first touch is obtained,
Further comprising an access authority granting unit for communicatively connecting the own terminal and the other terminal based on the information on the other terminal provided to the own terminal when the own terminal and the other terminal are first connected to each other by communication,
wherein the coordinate data conversion unit acquires the coordinate data of the second touch with respect to the other terminal communicatively connected to the magnetic terminal. The method of claim 1,
Further comprising a processing speed determination unit for determining whether the data processing speed of the at least two other terminals is equal to or greater than the data processing speed of the own terminal,
wherein the coordinate data transmission control unit transmits the coordinate data of the first touch in real time or non-real time based on a result of determining the processing speed of the at least two other terminals. The method of claim 1,
The interactive touch screen device, characterized in that when the coordinate data conversion unit acquires the coordinate data of the second touch, it also acquires information on the resolution of the second touch panel. delete delete delete delete delete delete delete delete delete delete delete delete delete

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