KR100861065B1 - Device and method for transmitted and received data - Google Patents

Abstract

According to an embodiment of the present invention, a data transmission / reception apparatus receives digital data having an image frame format on a frame basis, and receives control signal information including at least one of an intensity correction signal, a tilt correction signal, and a synchronization signal for each frame of the digital data. The digital signal by generating and storing in each frame and displaying the digital data as image data, photographing image data displayed by the transmitter, and restoring the photographed image data to digital data in the image frame format. A receiver for acquiring data.

Transmitter, Receiver, Display Unit, Mobile Terminal, Camera Unit

Description

DEVICE AND METHOD FOR TRANSMITTED AND RECEIVED DATA}

The present invention relates to an apparatus and method for transmitting and receiving data, and an apparatus and method for transmitting and receiving data through a transmitter (display apparatus) capable of receiving and displaying digital data and a receiver capable of capturing and receiving digital data. It is about.

Currently, portable terminals are transforming into structures capable of transmitting high-speed data in addition to voice communication functions. A function of capturing image data by adding a camera to the portable terminal is implemented, and a digital camera is generally used as a camera provided in the portable terminal. If the portable terminal is capable of receiving data of a digital signal as well as capturing image data through the digital camera and processing the same, it may be convenient to receive high-speed data at a distance that can be captured by the camera at a short distance.

Accordingly, an object of the present invention is to provide a data transmission / reception apparatus and method for transmitting and receiving data through a transmitter (display device) capable of receiving and displaying digital data and a receiver capable of capturing and receiving digital data.

According to an embodiment of the present invention, a data transmission / reception apparatus receives digital data having an image frame format on a frame basis, and receives control signal information including at least one of an intensity correction signal, a tilt correction signal, and a synchronization signal for each frame of the digital data. The digital signal by generating and storing in each frame and displaying the digital data as image data, photographing image data displayed by the transmitter, and restoring the photographed image data to digital data in the image frame format. A receiver for acquiring data.

In addition, the present invention provides a method for transmitting and receiving data, the process of receiving digital data having an image frame format in the frame unit in the transmitter, and the intensity correction signal, the tilt correction signal and the synchronization signal for each frame of the digital data in the transmitter Generating and storing control signal information including at least one of the control signal information in each frame; displaying the digital data as image data; and receiving and receiving digital data displayed by the transmitter from a receiver. Acquiring the digital data by reconstructing the image data into the digital data of the image frame format.

As described above, the present invention transmits and receives data using a display device capable of receiving and displaying digital data and a mobile terminal capable of capturing and receiving digital data, thereby receiving short-range data that can replace conventional mobile broadcasting. It is possible to provide a function, and in particular, a large screen or LCD TV in a public place can be used as a data communication function in a multi-user environment.

DETAILED DESCRIPTION Hereinafter, detailed descriptions of preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same components in the figures represent the same numerals wherever possible.

1 is a diagram illustrating data transmission and reception in data transmission and reception according to an embodiment of the present invention. In the embodiment of the present invention, it is assumed that the transmitter is a display device capable of receiving and displaying digital data, and the receiver is assumed to be a portable terminal capable of capturing and receiving digital data.

Referring to FIG. 1, the data service provider 300 transmits digital broadcast data and data such as news, weather and traffic information to the display device 200 as compressed digital data.

The data service provider 300 compresses the data into an audio codec such as H.264 and a video codec such as MPEG4, and compresses the compressed data of an existing portable broadcasting transmission method such as real-time streaming or file-delivery. The transmission format may be transmitted to the display device 200.

In addition, the data service provider 300 transmits the digital data to the display device 200 in units of frames, and each frame of the digital data transmitted in units of frames includes at least one data channel. The channel information is stored in each data channel.

Each frame includes a configuration information of a data channel, that is, a position value of a pixel in which a corresponding data channel is stored in all frames, display information for displaying the frame on the display device 200, frame size information, and the like. The information is stored. In addition, compression information, variable data rate information, and the like are stored in the channel information corresponding to each data channel.

The display device 200 performs a function of inputting and displaying digital data and is a display device that can be mounted in outdoor / indoor spaces, homes, workplaces, and vehicles, and includes digital camera pixels such as VGA / SVGA / XGA grades. It is composed of resolution that can decompose number.

The display apparatus 200 performs a function of receiving and displaying digital data received from the data service provider 300 in units of frames, that is, a corresponding frame composed of at least one data information.

Looking at the configuration of the display device 200, the receiver 210 receives the frame of the digital data from the data service provider 300 in units of frames through wireless communication. In this case, the received frame includes and stores at least one data channel, frame information including configuration information of the data channel, display information for displaying the frame on the display device 200, frame size information, and the like. have.

The image buffer 220 includes control signal information in the corresponding frame of the received digital data and stores the frame in units of frames, and outputs the corresponding frame of the digital data in which the control signal information is stored to the first display unit 230.

The first display unit 230 displays a corresponding frame of digital data in which a control signal stored in the image buffer 220 is stored. The digital data displayed on the first display unit 230 is data used in wireless communication, not general image data, and thus is not visually identifiable image data. 2 illustrates a frame corresponding to the digital data in which the intensity correction signal, the tilt correction signal, and the synchronization signal, which are control signals stored in the image buffer 220, are stored. In FIG. 2, the intensity reference column indicates a predetermined position where pixel data values corresponding to the intensity correction signal are stored, and the first reference value to the fourth reference value extract the tilt of the corresponding frame from the tilt correction signal. The reference value for the correction is shown. In addition, the synchronization reference column indicates a predetermined position at which the synchronization signal for informing a number of a corresponding frame is stored, and the channel information is a position of a pixel in which at least one channel information stored in one frame is stored. The value is shown.

 In FIG. 2, the control signal, the intensity correction signal, the tilt correction signal, and the synchronization signal, will be described in detail in the operation description of the first control unit 240.

The first controller 240 controls the overall operation of the display device 200. The first controller 240 generates control signal information through frame information stored in a corresponding frame of digital data received through the receiver 210. In addition, the first controller 240 controls the control signal information to be included in the frame of the digital data and stored in the image buffer 220, and includes the control signal information stored in the image buffer 220. The corresponding frame of the digital data is output to the first display unit 230 to control the display. In this case, the first control unit 240 controls to display the corresponding frame on the first display unit 230 through the display information of the frame information stored in the corresponding frame. The display information includes data information (RGB / YUV), horizontal / receive sync information, pixel clock information, etc. for displaying the corresponding frame on the first display unit 230.

The first controller 240 generates the control signal information including the intensity correction signal, the tilt correction signal, and the synchronization signal through the frame information stored in the corresponding frame. FIG. 2 is a diagram illustrating a configuration of a corresponding frame of digital data displayed on the first display unit 230. The intensity correction signal, the tilt correction signal, and the synchronization signal will be described with reference to FIG. 2.

The intensity correction signal is used to correct the intensity of pixel data of a corresponding frame of digital data photographed by the mobile terminal 100 and is stored with a predetermined same pixel data value at a predetermined position of the frame.

For example, when the size of the corresponding frame is 640 * 480 as shown in FIG. 2, predetermined positions (intensity reference columns) in which the intensity correction signal is stored are (238,0)-(238,639), which are rows of intermediate pixels. ), And a predetermined pixel value having each intermediate RGB value as the pixel data value corresponding to the intensity correction signal is equally stored at the predetermined positions.

 Therefore, when the mobile terminal 100 receives the corresponding frame, the actual pixel data value and the intensity located at (238,0)-(238,639), which are predetermined positions in which the intensity correction signal is stored in the corresponding frame. If the pixel data values corresponding to the correction signals are not matched and matched with each other, it is recognized that an error has occurred in all pixel data of the corresponding frame, and the intensity correction is performed on the entire pixel data. The intensity correction may be performed by adding the extracted value by dividing the pixel data value corresponding to the intensity correction signal by the actual pixel data value to the pixel data value located in the corresponding column, respectively.

In addition, the tilt correction signal is a signal for correcting the tilt of the corresponding frame when the mobile terminal 100 is not parallel or shakes when photographing the digital data displayed on the display device 200.

The tilt correction signal has at least one reference value, and when the size of the frame is out of the reference value, the tilt correction signal is determined to be tilted, and the tilt information of the corresponding frame is extracted and corrected.

For example, as shown in FIG. 2, when the size of the corresponding frame is 640 * 480, the first reference value (1 to n, 0), the second reference value (1 to n, 639), and the third reference value ( 479-n to 479 and 0) and at least one of the fourth reference value (479-n to 479 and 639) may be the reference value. When the tilt correction signal has the first to fourth reference values, if the corresponding frame deviates from a position corresponding to the reference values, it is determined that the corresponding frame is tilted. Then, the degree of tilt of the corresponding frame is extracted, and the corresponding pixel data value corresponding to the degree of tilt is read and the output is displayed again to the position where the tilt is corrected.

In addition, the synchronization signal performs a function for informing the number of the corresponding frame of the digital data photographed by the mobile terminal (100). As shown in FIG. 2, the synchronization signal is stored as a predetermined pixel value at a predetermined position (n + 1 to 479 -n, 0) of the corresponding frame.

 The portable terminal 100 captures and receives digital data displayed on the display device 200, and restores the received digital data to display corresponding data information. The configuration of the portable terminal 100 will be described in detail with reference to FIG. 3.

3 is a diagram illustrating a configuration of the mobile terminal 100 according to an embodiment of the present invention.

Referring to FIG. 3, the RF unit 123 performs a wireless communication function of the portable terminal. The RF unit 123 includes an RF transmitter for upconverting and amplifying a frequency of a transmitted signal, and an RF receiver for low noise amplifying and downconverting a received signal. The modem 120 includes a transmitter for encoding and modulating the transmitted signal, a receiver for demodulating and decoding the received signal, and the like.

The audio processor 125 may configure a codec, and the codec includes a data codec for processing packet data and an audio codec for processing an audio signal such as voice. The audio processor 125 converts and reproduces the digital audio signal received from the modem 120 into an analog signal through the audio codec or outputs an analog audio signal generated from a microphone and transmitted through the audio codec through the audio codec. Convert to and transmits to the modem (120). The codec may be provided separately or included in the second control unit 110.

The memory 130 may be composed of program memory and data memories. The program memory may store programs for controlling a general operation of the portable terminal and programs for restoring digital data received from the camera unit and displaying corresponding data information according to an embodiment of the present invention. The data memory also temporarily stores data generated during the execution of the programs.

The second control unit 110 performs a function of controlling the overall operation of the mobile terminal. In addition, the second control unit 110 may include the modem 120 and the codec. In addition, the second control unit 110 extracts the control signal information stored in the corresponding frame of the digital data photographed and received by the camera unit 140 according to an embodiment of the present invention, and the control unit through the control signal information Correct it.

The control signal information includes an intensity correction signal, a tilt correction signal, and a synchronization signal, and the second controller 110 corresponds to pixel data values constituting the corresponding frame and the intensity correction signal through the intensity correction signal. When the pixel data values do not coincide, the control is performed to correct the intensity of the pixel data constituting the corresponding frame to a predetermined value. In addition, the second controller 110 extracts the degree of tilt of the corresponding frame when the size of the corresponding frame deviates from at least one reference value corresponding to the tilt correction signal through the tilt correction signal among the control signal information. The number of the corresponding frame is extracted through the synchronization signal among the control signal information.

The second controller 110 controls the second display unit 160 to restore the corrected frame and display the corresponding data information.

The camera unit 140 controls to correct the intensity of pixel data of a corresponding frame of digital data photographed by the camera unit 140. In addition, the second control unit 110 controls to extract and correct the degree of tilt of the corresponding frame of the digital data photographed by the camera unit 140 through the tilt correction signal. In addition, the second control unit 110 controls to extract the number of the corresponding frame of the digital data photographed by the camera unit 140 through the synchronization signal.

In addition, the second controller 110 controls to display the corresponding data information, that is, at least one data channel information constituting the corresponding frame, by restoring the corresponding frame according to an embodiment of the present invention.

The camera unit 140 photographs image data, and includes a camera sensor for converting the photographed optical signal into an electrical signal, and a signal processor for converting the analog image signal photographed from the camera sensor into digital data. Herein, it is assumed that the camera sensor is a CCD sensor, and the signal processor may be implemented by a digital signal processor (DSP). In addition, the camera sensor and the signal processor may be integrally implemented or may be separately implemented.

In addition, the camera unit 140 receives the data of the digital signal according to an embodiment of the present invention, and transmits the data of the received digital signal to the image processor 150.

The image processor 150 performs a function of generating screen data for displaying an image signal output from the camera unit 140. The image processor 150 processes the image signal output from the camera unit 140 in units of frames, and outputs the frame image data according to the characteristics and the size of the second display unit 160. In addition, the image processor 150 includes an image codec, and compresses the frame image data displayed on the second display unit 160 in a set manner or restores the compressed frame image data to the original frame image data. Perform. The image codec may be a JPEG codec, an MPEG4 codec, a wavelet codec, or the like. It is assumed that the image processor 150 has an On Screen Display (OSD) function, and may output on-screen display data according to a screen size displayed under the control of the second controller 110.

In addition, the image processor 150 restores the frame of the digital data photographed and received by the camera unit 140 to the original corresponding data according to an embodiment of the present invention, and restores the restored corresponding data information. 2 is output to the display unit 160.

The second display unit 160 displays an image signal output from the image processor 150 on a screen and displays user data output from the second control unit 110. The second display unit 160 may use an LCD. In this case, the second display unit 160 may include an LCD controller, a memory capable of storing image data, and an LCD display device. In this case, when the LCD is implemented using a touch screen method, the LCD may operate as an input unit. In addition, the second display unit 160 displays corresponding data information input from the image processor 150, that is, at least one data channel information configured in the corresponding frame, according to an exemplary embodiment of the present invention.

The key input unit 127 includes keys for inputting numeric and character information and function keys for setting various functions.

The operation of transmitting and receiving data through the transceiver configured as described above will be described in detail with reference to FIG. 4.

4 is a flowchart illustrating a data transmission and reception process according to an embodiment of the present invention.

An embodiment of the present invention will now be described in detail with reference to FIGS. 1 to 3.

Referring to FIG. 4, when the data service provider 300 transmits digital data including at least one data channel to each of the display apparatuses 200 in step 301, the data service provider 300 controls the display apparatus 200. The first control unit 240 detects this in step 302 and receives the corresponding frame of the digital data through the receiving unit 210. The first controller 240 proceeds to step 303 of generating intensity correction signals, tilt correction signals, and synchronization signals, which are control signal information, through frame information stored in the corresponding frame of the digital data. In operation 304, the first controller 240 includes the generated control signal information in the corresponding frame of the digital data and stores the generated control signal information in the image buffer 220 in units of frames. The first controller 240 displays the corresponding frame of the digital data including the control signal information stored in the image buffer 220 on the first display unit 230 through display information included in the frame information. The control proceeds to step 305.

While displaying the corresponding frame of digital data on the first display unit 230 of the display device 200, the digital data is stored through the camera unit 140 in step 306, which is a camera photographing mode of the portable terminal 110. When the frame is received, the second control unit 110, which is a control unit of the portable terminal, detects it in step 307 and performs steps 308 to 310 of correcting the corresponding frame of the digital data.

The second controller 110 extracts control signal information included in the corresponding frame of the digital data, and performs correction on the corresponding frame through the intensity correction signal, the tilt correction signal, and the synchronization signal which are the control signal information. .

In operation 308, the second controller 110 performs intensity correction on a corresponding frame of digital data. In operation 308, the second control unit 110 controls the intensity correction signal and the actual pixel data value stored at predetermined positions where the intensity correction signal is stored in the corresponding frame through the intensity correction signal. Compare the pixel data value corresponding to. If the actual pixel data value and the pixel data value corresponding to the intensity correction signal do not match, the second controller 110 corrects the pixel data constituting the corresponding frame to a predetermined value.

After the intensity correction is performed, the second controller 110 performs tilt correction on the corresponding frame of the digital data in step 309. In operation 309, the second controller 110 determines whether the size of the corresponding frame deviates from at least one reference value corresponding to the tilt correction signal, that is, at least one reference value set according to the size of the corresponding frame. do. If it is determined that the frame is out of the at least one reference value, the second control unit 110 detects it and determines that the tilt is generated by photographing the corresponding frame, and tilts it through the at least one reference value. The degree of inclination is extracted to correct the degree of inclination of the corresponding frame.

In operation 310, the second controller 110 extracts a number of the corresponding frame of the digital data through the synchronization signal.

When the correction is performed on the frame in step 308 to 310, the second controller 110 detects this and controls the frame to be restored to the original data through the image processor 150. Proceed to step 311.

The second controller 110 proceeds to step 312 of displaying the corresponding data information restored in step 311 on the second display unit 160. In step 312, the second data unit 160 displays the corresponding data information. At least one data channel configured in the corresponding frame may be displayed.

In addition, when a predetermined data channel among the at least one data channel displayed on the second display unit 160 is selected, information on the selected data channel may be displayed, and the selected channel may be reproduced and displayed.

In the present invention, the data transmission rate for transmitting data from the display device 200 corresponding to the transmitter to the portable terminal 100 corresponding to the receiver is "300kbps (pixel speed) * 256" based on VGA (640 * 480). color-depth) * 30 frame = 2.3 Gbps ". When compressed with the current H.264 codec (384kbps, QVGA 30frame), 256 QVGA-class broadcasting contents can be received in a multi-user environment. In addition, in the case of general data transmission (web-service, e-mail, streaming, up-link channels are also configured), data can be transmitted at 2.3Gbps.

In the above description of the present invention, a specific embodiment such as a mobile terminal has been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

1 is a diagram illustrating data transmission and reception in data transmission and reception according to an embodiment of the present invention.

 FIG. 2 is a diagram illustrating a configuration of a corresponding frame of digital data displayed on a display unit of the transmitter in FIG.

3 is a diagram showing the configuration of a receiver in FIG.

4 is a flowchart illustrating a data transmission and reception process according to an exemplary embodiment of the present invention.

Claims (14)

In the data transmission and reception apparatus, Receiving digital data having an image frame format on a frame-by-frame basis, generating control signal information including at least one of an intensity correction signal, a tilt correction signal, and a synchronization signal for each frame of the digital data; A transmitter for displaying the digital data as image data; And a receiver for capturing the image data displayed by the transmitter and acquiring the digital data by reconstructing the photographed image data into the digital data of the image frame format. The method of claim 1, And a data service provider for transmitting digital data having an image frame format to the transmitter in units of frames. The method according to claim 1 or 2, Each frame of the digital data is composed of at least one data channel, wherein each of the data channels includes corresponding channel information. The method of claim 1, wherein the transmitter, A receiving unit for receiving the digital data; An image buffer including control signal information in a corresponding frame of the digital data including at least one data channel and storing the information in a frame unit; A display unit for displaying a corresponding frame of the digital data stored in the image buffer; Control signal information is generated through frame information stored in a corresponding frame of the digital data, and the control signal information is included in the corresponding frame of the digital data including the at least one data channel and stored in the image buffer in a frame unit. And a controller which controls to display the corresponding frame of the digital data stored in the image buffer on the display unit. The method of claim 4, wherein The controller generates the control signal information including at least one of an intensity correction signal, a tilt correction signal, and a synchronization signal based on the frame information stored in the corresponding frame, and stores the control signal information in a predetermined position of the corresponding frame. The intensity correction signal corrects an intensity of pixel data of a corresponding frame of digital data photographed by a receiver, and the tilt correction signal corrects a tilt of a corresponding frame of digital data photographed by the receiver, and the synchronization signal And transmitting a number of a corresponding frame of the digital data photographed by the receiving unit. The method of claim 1, wherein the receiver, A camera unit for photographing the digital data displayed by the transmitter; An image processing unit for outputting digital data obtained by restoring image data photographed by the camera unit to a display unit; When the corresponding frame of the digital data is photographed and received through the camera unit, the control signal information included in the corresponding frame is extracted to correct the corresponding frame, and the digital data obtained by restoring the corresponding frame is displayed on the display unit. Data transmission and reception apparatus comprising a control unit for controlling. The method of claim 6, The controller controls the pixel data constituting the frame to be a predetermined value if the pixel data value constituting the frame and the pixel data value corresponding to the intensity correction signal do not match through the intensity correction signal in the control signal information. Corrected by; Extracting and correcting an inclination degree of the corresponding frame when the size of the corresponding frame deviates from at least one reference value corresponding to the inclination correction signal through the inclination correction signal in the control signal information; And a number of the corresponding frame is extracted through the synchronization signal from the control signal information. The method of claim 1, The transmitter is a display device capable of inputting and displaying digital data, and the receiver is a mobile terminal including a digital camera unit. In the data transmission and reception method, Receiving digital data having an image frame format from a transmitter in units of frames, Generating, by the transmitter, control signal information including at least one of an intensity correction signal, a tilt correction signal, and a synchronization signal for each frame of the digital data; Displaying the digital data as image data; And receiving and receiving digital data displayed by the transmitter from a receiver, and acquiring the digital data by reconstructing the photographed image data into the digital data of the image frame format. The method of claim 9, wherein the receiving and displaying the digital data comprises: Receiving a corresponding frame of the digital data composed of at least one data channel at the transmitter; Generating control signal information through frame information stored in a corresponding frame of the digital data; Storing the control signal information in a corresponding frame of the digital data; And outputting and displaying a corresponding frame of the digital data including the control signal information. The method of claim 10, wherein the generating of the control signal information comprises: Generating an intensity correction signal among the control signal information through frame information stored in a corresponding frame of the digital data and storing the intensity correction signal in a predetermined position of the corresponding frame; Generating a tilt correction signal of the control signal information using frame information stored in a corresponding frame of the digital data and storing the tilt correction signal at a predetermined position of the corresponding frame; And generating a synchronization signal among the control signal information through frame information stored in a corresponding frame of the digital data, and storing the number of the corresponding frame at a predetermined position of the corresponding frame. The method of claim 9, wherein displaying the corresponding data comprises: Photographing and receiving the digital data displayed by the transmitter in the receiver; Correcting a corresponding frame of the received digital data through control signal information; Restoring a corresponding frame of the corrected digital data to display corresponding data information. The method of claim 12, wherein the correcting the control signal information comprises: Extracting control signal information stored in a corresponding frame of the received digital data; If the pixel data value constituting the corresponding frame and the pixel data value corresponding to the intensity correction signal do not coincide with the intensity correction signal among the control signal information, the pixel data constituting the corresponding frame is corrected to a predetermined value. Process, Extracting and correcting a tilt degree of the corresponding frame when the size of the corresponding frame deviates from at least one reference value corresponding to the tilt correction signal through the tilt correction signal among the control signal information; And extracting a number of the corresponding frame through a synchronization signal among the control signal information. The method of claim 9, The transmitter is a display device capable of inputting and displaying digital data, and the receiver is a portable terminal including a digital camera unit.

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