KR20050026266A - Device and method for displaying multiple channel in mobile terminal with television - Google Patents

Abstract

An apparatus and a method for displaying plural channels in a mobile phone having a television function are provided to display plural channel screens at the same time so that a user can watch a desired channel at a desired time zone. If a TV key is pushed lengthily(401), a control part sets a TV mode(402). The control part outputs control data to select a TV channel(403). The TV channel control data are outputted to a tuner through a control interface and an I^2C master. At this moment, if a channel is not appointed, the control part outputs channel control data so as to access a previously appointed channel. The tuner executes frequency conversion for the first image signal, tuned and received according to the previously appointed channel. In case that a multi-channel view mode is set(404), the control part respectively outputs control data to select the TV channels of the second through fifth image signals. The TV channel control data are also outputted to the tuner through the control interface and an I^2C master. The tuner carries out frequency conversion for the second through fifth image signals.

Description

TECHNICAL FIELD [0001] The present invention relates to a multi-channel display and a method for a mobile terminal having a television function. {DEVICE AND METHOD FOR DISPLAYING MULTIPLE CHANNEL IN MOBILE TERMINAL WITH TELEVISION}

The present invention relates to a portable terminal having a television function, and more particularly, to an apparatus and method capable of displaying a plurality of channels through the portable terminal having one tuner.

Currently, portable terminals are transforming into structures capable of transmitting high-speed data in addition to voice communication functions. That is, by implementing a mobile communication network of the IMT 2000 standard, it is possible to implement high-speed data communication in addition to voice communication using the portable terminal. Data that can be processed by the mobile terminal performing the data communication may be packet data and image data.

In addition, the portable terminal includes a display unit, and the size of the display unit is gradually increasing. In addition, portable terminals capable of displaying picture data (pixel data) received from a base station together or processing data photographed from a camera have also emerged. The portable terminal may receive and display a television video signal. In this case, a television reception function should be added to the portable terminal, and it should be possible to perform a radio communication function simultaneously or independently while processing the television signal.

However, the portable terminal to which the television reception function is added does not show only one screen to the user with a single tuner, and provides only static screens when multiple screens are displayed at the same time. Therefore, it was impossible for the user to know the situation of the various channels and to watch the program in a timely manner.

Accordingly, an object of the present invention is to provide an apparatus and method for simultaneously displaying screens of several channels through one tuner.

A device for displaying at least two television video signals in a portable terminal for achieving the above object includes a tuner for receiving the television video signal and a decoder for decoding the received composite video signal to generate analog video signals and synchronization signals. And an image processing unit converting the analog image signal into digital image data and processing the maximum frame or minimum frame size, and outputting the maximum frame or minimum frame image data in the frame section. And a display unit including a first display unit for displaying the maximum frame image data and a second-nth display unit for displaying the minimum frame image data, respectively.

In addition, a display unit including a first display unit for displaying the image data of the maximum frame and a second to n-th display unit for displaying the image data of the minimum frame, and an image processing unit including the first to third memories for achieving the above object. A method of displaying at least two television image data in a portable terminal comprises the steps of receiving a first-n-th image data by controlling a tuner in a television mode, displaying the first image data on the first display unit, Displaying the second-n-th image data on the second-n-th display unit, updating the first image data, and displaying the first image data on the first display unit, and when the predetermined time elapses. Pausing the update of the image data, updating the image data of one of the second to n-th image data and returning to the updating process of the first image data. The bags feature.

In addition, a display unit including a first display unit for displaying the image data of the maximum frame and a second to n-th display unit for displaying the image data of the minimum frame, and an image processing unit including the first to third memories for achieving the above object. A method of displaying at least two television image data in a portable terminal comprises the steps of receiving a first-n-th image data by controlling a tuner in a television mode, displaying the first image data on the first display unit, Displaying the second-n-th image data on the second-n-th display unit, updating the first image data, and displaying the second-n-th image data on the first display unit; When the image data for channel conversion is selected, a process of stopping updating of the first image data and scaling the received first image data to the minimum frame image data to generate a second memo. A second process of storing the first image data stored in the second memory, block copying and displaying the first image data stored in the second memory in the first memory area of the selected image data, and receiving the selected image data as a maximum frame image data. Scaling and storing the selected image data stored in the second memory, displaying the selected image data on the first display unit, updating the selected image data, and displaying the selected image data on the first display unit. Characterized in that made.

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.

In the following description, specific details such as the number of pixels of one frame, the number of scaled maximum and minimum frames, the number of display units capable of displaying the minimum frame, etc. are shown to provide a more general understanding of the present invention. It will be apparent to one of ordinary skill in the art that the present invention may be readily practiced without these specific details and also by their modifications.

1 is a diagram illustrating a configuration of a portable terminal device according to an exemplary embodiment of the present invention. The portable terminal may be a mobile telephone.

Referring to FIG. 1, the RF unit 21 performs wireless communication of a mobile phone. The RF unit 21 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 data processor 23 includes a transmitter for encoding and modulating the transmitted signal and a receiver for demodulating and decoding the received signal. That is, the data processor 23 may be configured of a modem and a codec CODDEC. The audio processor 25 plays a function of reproducing a received audio signal output from the data processor 23 or transmitting a transmission audio signal generated from a microphone to the data processor 23.

The keypad 27 is provided with keys for inputting numeric and text information and function keys for setting various functions. In addition, the keypad 27 includes various mode setting keys for processing at least two television video signals according to an exemplary embodiment of the present invention.

The memory 29 may be composed of program memory and data memories. The program memory may store programs for controlling a general operation of the mobile phone and programs for processing at least two television video signals according to an embodiment of the present invention. In addition, the data memory 29 temporarily stores data generated during the execution of the programs.

The controller 10 performs a function of controlling the overall operation of the mobile phone. In addition, the controller 20 may include the data processor 23. In addition, the controller 10 sets the image processor 70 to the television mode when the mode setting is changed from the keypad 27 according to an embodiment of the present invention, and controls to display at least two television video signals received according to the set television mode. In addition, the controller 10 controls to update the screen of the display units when a preset time elapses, according to an embodiment of the present invention. In addition, the control unit 10 controls to display the image data according to the channel conversion request according to an embodiment of the present invention.

The tuner 50 receives a television video signal of a selected channel under the control of the controller 10 and performs a function of frequency converting the received television video signal. The tuner 50 receives at least two image signals in the embodiment of the present invention, and in the embodiment of the present invention, the tuner 50 receives the first to fifth image signals.

The decoder 60 demodulates and decodes the television video signal output from the tuner 50. The decoder 60 decodes the television video signal and outputs color signal R, G, and B and a synchronization signal (a horizontal synchronization signal and a vertical synchronization signal).

The image processor 70 communicates data with the controller 10 and performs a signal processing function for displaying the television image signal output from the decoder 60 under the control of the controller 10. The image processor 70 processes the image signal output from the decoder 60 and the user data output from the controller 10 and outputs the same to the corresponding area of the display unit 80. In this case, the user data includes a current time, battery level indication, reception sensitivity, and the like, and also means status data according to a state change of the television mode. The image processor 70 processes and outputs the television signal in a frame size, and separately outputs the television image data and the user data. In addition, the image processing unit 70 processes and outputs the television video signal to a maximum frame size and a minimum frame size in a television mode according to an embodiment of the present invention.

The display unit 80 displays data output from the control unit 10 in a communication mode, and displays television image data and user data output from the image processing unit 70 in a corresponding area in the television mode. The display unit 80 may use an LCD. In this case, the display unit 80 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 by using a touch screen method, the keypad 27 and the LCD may be input units.

In addition, the display unit 80 includes a first display unit and a second-n-th display unit according to an exemplary embodiment of the present invention. The display unit 80 displays the image data of the maximum frame output from the image processor 70 and displays the image processor 70. The minimum frame image data output from the display is respectively displayed on the second to n-th display units. In the embodiment of the present invention, it is assumed that the display unit 80 includes a first display unit for displaying image data of the maximum frame output from the image processor 70 and a second to fifth display unit for displaying image data of the minimum frame.

  Referring to FIG. 1, the operation of a mobile phone displaying a television screen is described. First, when a user performs a dialing operation through a keypad 27 in a communication mode and presses a call key, the controller 10 detects this and the data processor 23. After processing the dial information received through the RF unit 21 converts the RF signal and outputs. Thereafter, when the counter subscriber generates a response signal, the counter subscriber detects this through the RF unit 21 and the data processor 23. Thereafter, a user establishes a voice call path through the audio processor 25 to perform a communication function. In addition, in the incoming mode, the controller 10 detects the incoming mode through the data processor 23 and generates a ring signal through the audio processor 25. Thereafter, when the user responds, the control unit 10 detects this, and a voice call path is formed through the audio processing unit 25 to perform a communication function. In the outgoing and incoming modes, voice communication is described as an example, but a data communication function for communicating packet data and image data in addition to the voice communication may be performed. In addition, when performing a standby mode or text communication, the controller 10 displays text data processed by the data processor 23 on the display 80.

Second, look at the operation in the television mode. FIG. 2 is a diagram illustrating a television receiver configuration according to an embodiment of the present invention in the configuration of FIG. 1.

Referring to FIG. 2, the operation of the television mode of the mobile phone is described. When the user selects the television mode, the controller 10 notifies the image processor 70. The image processor 70 then outputs control data for selecting a channel to the tuner 50 and drives the decoder 60. Then, the tuner 50 is tuned to a channel corresponding to the channel control data output from the image processor 70, and receives and frequency-converts a television video signal received through the tuned channel and outputs the same to the decoder 60.

The decoder 60 decodes the received television video signal and outputs an RGB analog video signal and a synchronization signal (horizontal and vertical synchronization signals). The decoder 60 separates and outputs color signals from the received composite video signal. The decoder 60 may be an NTSC decoder.

The image processor 70 receiving the RGB image signal and the synchronization signals output from the decoder 60 adds user data to the television video signal and displays the same on the display unit 80. In this case, the user data may be user data output from the controller 10. The user data may be generated by the image processor 70 under the control of the controller 10. The user data is displayed on the television video signal in the form of an on screen display (OSD).

The image processing unit 70 inputs an RGB analog television video signal, converts the analog video signal into digital data by using an analog-to-digital converter (ADC), and scales and stores the digital data in a corresponding frame size. After that, it outputs to the display unit 80. In addition, the image processing unit 70 may display the user data output from the controller 10 or user data generated therein under the control of the controller 10 by using an OSD, and a capture function of the displayed television screen and a block of the OSD. It has a copy function.

3 illustrates a detailed block configuration of the image processor 70 of FIGS. 1 and 2. Referring to FIG. 3, the operation of the image processor 70 will be described. The A / D converter 111 may digitally convert an RGB analog signal output from the decoder 60. Here, it is assumed that the A / D converter 111 converts the RGB analog signal into 18-bit RGB digital data (65536 colors).

A scaler 113 inputs the RGB digital data output from the A / D converter 111 and the horizontal synchronizing signal HSYNC and the vertical synchronizing signal VSYNC output from the decoder 60, and converts the RGB digital data based on the synchronization signals. Scale the size. The scaling operation is as follows. First, determine the display image size. Secondly, the size VXSIZE and VYSIZE are set for each of the horizontal and vertical positions of the determined display image size. In an embodiment of the present invention, it is assumed that the television video signal is scaled from a maximum of 220 * 176 pixels to a minimum of 100 * 75 pixels. Third, set the scaling factor (zoom factor). Fourth, in the horizontal direction, 720 * 4096 / VXSIZE is calculated and set to HLSR, and in the vertical direction, 240 * 2048 / VYSIZE is calculated and set to VLSR. In the embodiment of the present invention, it is assumed that the input image signal is scaled to a maximum frame of 220 * 176 pixels or to a minimum frame of 100 * 75 pixels. The scaler 113 converts the RGB 18-bit data into RGB 16-bit data. Here, the 16-bit data [15: 0] is 5 bits of R (Red) data [15:11], 6 bits of G (Green) data [10: 5] and 5 bits of B (Blue) data [4 : 0].

The first to third memories 131, 132, and 133 are memories that store data having a frame size. In an embodiment of the present invention, the first memory 131 is used as a memory for storing user data and data having a minimum frame size (75 * 100 * 12 bits), and the first memory 131 is used for storing the minimum frame data. Second-n-th region. An embodiment of the present invention will be described on the assumption that regions for storing the minimum frame data are configured as second to fifth regions. In addition, the second memory 132 is used as a memory for storing data having a maximum frame size (176 * 220 * 12 bits) and data having a minimum frame size (75 * 100 * 12 bits), and the third memory 133 is a maximum frame. It is used as a memory to store data of size (176 * 220 * 12 bits).

The memory controller 123 controls the access of the memories 131, 132, and 132 under the control of the controller 10. The memory 123 separately controls the memories 131, 132, and 133 according to a television mode and a communication mode. First, in the television mode, the memory controller 123 accesses the user data output from the controller 10 to the first memory 131 according to an embodiment of the present invention, and the scaler 113 in the second memory 132 (or the third memory 133). Stores the current maximum frame image data output from and outputs the previous maximum frame image data stored in the third memory 133 (or second memory 132). The memory controller 123 stores and outputs RGB image data of the television received in the memories 132 and 133 in units of maximum frames. In this case, when the current maximum frame image data is stored in the memory 132, the image data of the previous maximum frame stored in the memory 133 is output, and when the image data of the current maximum frame is stored in the memory 133, the previous stored in the memory 132 Output image data of maximum frame. That is, the memory controller 123 processes the television video signal in real time by storing the maximum frame data received when the memory 132 and 133 are accessed and outputting the previous maximum frame data. That is, the video signal is transmitted to the first display unit 81 in real time using two frame memories, and the screen of the first display unit 81 is updated.

In addition, when a preset time elapses by the timer included in the portable terminal according to an exemplary embodiment of the present disclosure, the memory controller 123 stops updating the screen of the first display unit 10 under the control of the controller 10, and then the first display unit is stopped. The maximum frame image data stored in the memory 133 is displayed on the first display unit 81. Thereafter, the minimum frame image data output from the scaler 113 is stored in the second memory 132, and the minimum frame image data stored in the second memory 132 is stored in a corresponding region of the second to fifth regions of the first memory 131. A block copy is made and transmitted to the corresponding display unit among the second to fifth display units 82-85. When the screen update of the display unit of the second to fifth display units is finished, the memory controller 123 performs the screen update process of the first display unit 10 again.

In addition, when the corresponding display unit is selected from the second to fifth display units for channel conversion, the memory controller 123 may receive the received image data displayed on the first display unit 81 from the second memory 132 in the scaler according to an exemplary embodiment of the present invention. The image data is stored as the minimum frame image data output from 113, and the minimum frame image data stored in the second memory 132 is block copied and displayed in the image data region of the display unit selected from the second to fifth regions of the first memory 131. The control unit may store the received image data of the selected display unit as maximum frame image data output from the scaler 113 in the second memory 132 and display the maximum frame image data stored in the second memory 132 on the first display unit 81. After that, the update process is performed through the second memory 132 and the third memory 133.

3 illustrates an embodiment of the present invention according to an image processor 70 having three memories. However, the embodiment of the present invention may be similarly applied to the image processor 70 having two memories as well as three memories. Assuming that the image processor 70 of FIG. 3 includes only the first memory 131 and the second memory 132, the following description will be given.

The first memory 131 and the second memory 132 are memories that store data having a frame size. In an embodiment of the present invention, the first memory 131 is used as a memory for storing user data and data having a minimum frame size (75 * 100 * 12 bits), and the first memory 131 is used for storing the minimum frame data. Second-n-th region. An embodiment of the present invention will be described on the assumption that regions for storing the minimum frame data are configured as second to fifth regions. In addition, the second memory 132 is used as a memory for storing data having a maximum frame size (176 * 220 * 12 bits) and data having a minimum frame size (75 * 100 * 12 bits).

The memory controller 123 controls the access of the first memory 131 and the second memory 132 under the control of the controller 10. The memory controller 123 classifies and controls the first memory 131 and the second memory 132 according to a television mode and a communication mode. First, in the television mode, the memory controller 123 accesses the user data output from the controller 10 to the first memory 131 according to an embodiment of the present invention, and the scaler 113 in the second memory 132 (or the third memory 133). Saves the maximum frame image data output from. When the image data is stored in the second memory 132 or the update signal is received from the controller 10, the memory controller 123 transmits the image data stored in the second memory 132 to the first display unit 81 and displays the screen of the first display unit 81. Update

In addition, when a preset time elapses by the timer included in the portable terminal according to an exemplary embodiment of the present disclosure, the memory controller 123 stops updating the screen of the first display unit 10 under the control of the controller 10, and then the first display unit is stopped. The maximum frame image data stored in the memory 133 is output to the first display unit 81 for display. Thereafter, the minimum frame image data output from the scaler 113 is stored in the second memory 132, and the minimum frame image data stored in the second memory 132 is stored in a corresponding region of the second to fifth regions of the first memory 131. The block copy is transmitted to the corresponding display unit of the second to fifth display units. When the screen update of the display unit of the second to fifth display units is completed, the memory controller 123 performs the screen update process of the first display unit 81 again.

In addition, when the corresponding display unit is selected from the second to fifth display units for channel conversion, the memory controller 123 may receive the received image data displayed on the first display unit 81 from the second memory 132 in the scaler according to an exemplary embodiment of the present invention. The image data is stored as the minimum frame image data output from 113, and the minimum frame image data stored in the second memory 132 is block copied and displayed in the image data region of the display unit selected from the second to fifth regions of the first memory 131. The control unit may store the received image data of the selected display unit as maximum frame image data output from the scaler 113 in the second memory 132 and display the maximum frame image data stored in the second memory 132 on the first display unit 81. After that, an update process is performed through the second memory 132.

Secondly, in the communication mode, the memory controller 123 uses the memory 131 and 132 as a memory for accessing user data, and the memory 133 serves as a memory for storing the background data. In this case, the memories 131 and 132 may be set and used without using them simultaneously.

The on-screen data mixer 125 mixes the image data of the frame size output from the memory controller 123 and the user data into on-screen data and outputs the on-screen data to the display unit 80. The control interface 117 interfaces user data and mode control data between the controller 10 and the image processor 70. I2C interface 115 has an I2C busmaster that can control two slave devices. The I 2 C interface 115 controls the tuner 50 and the decoder 60, and is controlled by the control interface 117. The OSD RAM Block Copy Accelerator 119 may copy an arbitrary rectangular area of the user data to an arbitrary position. The OSD controller 119 may block copy data of an arbitrary rectangular area to an arbitrary position by the control data of the controller 10 output from the control interface 117. The copy function is also possible in memory or between memories. The timing controller 121 generates a synchronization signal (horizontal synchronization signal HSYNC, vertical synchronization signal VSYNC) and a pixel clock DOTCLK detected in the television mode. The timing controller 121 controls the display unit 80 to be synchronized with the pixel, line image data, and frame image data of the image data output from the OSD mixer 125.

4A and 4B are flowcharts illustrating a method of displaying a plurality of channels in a mobile terminal according to an exemplary embodiment of the present invention, and FIGS. 5A through 5B are screens of a mobile terminal including an image processor including three memories. 6A to 6B are diagrams for explaining a screen updating process in a mobile terminal including an image processing unit having two memories, and FIG. It is a figure which shows the process of updating a channel screen.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1, 2, and 3. In the embodiment of the present invention, it is assumed that the first display unit 81 displays the video signal of the channel selected by the user, and the first video signal is assumed to be the video signal selected by the user. The first image signal received through the tuner is displayed on the first display unit 81, and the second and fifth image signals received through the tuner are displayed corresponding to the second and fifth display units 82-85, respectively. It is assumed and explained. However, the image data displayed on the second to fifth display units may be displayed in the order of the image signals received by the tuner. In the embodiment of the present invention, it is assumed that the second to fifth image signals are stored corresponding to the first to fifth regions of the first memory 131 of the image processor.

First, as shown in FIG. 5, when the portable terminal including the image processing unit having three memories displays a plurality of channels, when the TV key is pressed in a standby state, the controller 10 proceeds to step 401. This is detected and the TV mode is set in step 402. In step 403, the control unit 10 outputs control data for tuning the TV channel, and the TV channel control data is output to the tuner 50 through the control interface 117 and the I ² C master 115. In this case, if a channel is not designated after setting the TV mode, the controller 10 outputs channel control data to access a channel designated in a previous state. The tuner 50 then frequency-converts the first video signal received by being tuned to a designated channel, and the decoder 60 decodes the first video signal into an RGB analog video signal and a synchronization signal and outputs the same. Then, the A / D converter 111 converts the received analog first image signal into digital first image data, and the scaler 113 scales the digital first image data to a maximum frame size (176 * 220 * 12bit). The memory controller 123 stores the user data output from the controller 10 in the memory 131, stores the maximum frame image data in the second memory 132, and transmits the maximum frame image data to the first display unit 81.

The portable terminal is set to the multi-channel view, and the control unit 10 detects this in step 404 and outputs respective control data for tuning the TV channel of the second to fifth video signals. It is output to tuner 50 via control interface 117 and I ² C master 115. The tuner 50 then frequency-converts the second to fifth video signals, and the decoder 60 decodes the second to fifth video signals into an RGB analog video signal and a synchronization signal, respectively, and outputs the same. Then, the A / D converter 111 converts the received analog second- fifth image signal into a digital second- fifth image signal, and the scaler 113 converts the digital second- fifth image signal into a minimum frame (75 *). 100 x 12 bits). Then, the memory controller 123 stores the minimum frame image data in the second memory 132 and copies the block to the second to fifth regions 131-1 to 131-4 of the first memory 131 to display the second to fifth displays. Send to 82-85. If the mobile terminal is not set to the multi-channel view, the controller 10 detects this in step 404 and controls the memory controller 123 to transmit and display only the maximum frame image data to the first display unit 81 in step 420.

The memory controller 123 displays the first image data on the first display unit 81 and the second to fifth image data on the second to fifth display units 82 to 85 in step 405 under the control of the controller 10. In this case, the memory controller 123 controls the memory to display the real time by updating the first image signal received in step 406. In the process of updating the received first image signal in step 406, the maximum received frame image data is stored in the second memory 132 (or the third memory 133) and the third memory 133 (or the second memory). The digital image data of the previous maximum frame stored in 132 is output. When outputting image data of one frame is completed, the memory controller 123 outputs user data stored in the memory 131. Thereafter, when the image data of the next maximum frame is received, the memory controller 123 stores the received maximum frame image data in the third memory 133 (or the second memory 132) and simultaneously to the second memory 132 (or the third memory 133). Outputs the digital image data of the previous stored maximum frame. 5A illustrates a screen update process of the first display unit.

When the preset time (for example, 1 minute) elapses while updating the first image data as described above, the controller 10 detects this in step 407 and proceeds to step 408. In step 408, the memory controller 123 suspends the process of updating the first image data under the control of the controller 10, and displays the first image data stored in the third memory 133 on the first display unit 81. 2-Update the fifth image data. First, as shown in FIG. 7A, when the image data of the second display unit 82 is updated, the controller 10 detects it in step 409 and proceeds to step 413. If the received second image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113 in step 413, the memory controller 123 stores the minimum frame image data in the second memory 132. do. In operation 414, the memory controller 123 blocks the second image data stored in the second memory 132 to the second area 131-1 of the first memory 131 to update the screen of the second display unit 82. Proceed to step. 5B illustrates a screen update process of the second display unit. When the screen update process of the second display unit 82 is completed, the memory controller 123 again performs the screen update process of the first display unit 81 in step 406. When the set time elapses during the screen update process of the first display unit 81, the controller 10 detects this in step 407 and performs the third image data update process of the third display unit 83 as shown in FIG. 7B. .

When the image data of the third display unit 83 is updated, the control unit 10 detects this in step 410 and proceeds to step 413. When the received third image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113 in step 413, the memory controller 123 stores the minimum frame image data in the second memory 132. do. In operation 414, the memory controller 123 blocks the third image data stored in the second memory 132 into the third region 131-2 of the first memory 131 to update the screen of the third display unit 83. Proceed to step. When the screen update process of the third display unit 83 is completed, the memory controller 123 again performs the screen update process of the first display unit 81 in step 406. When the set time elapses during the screen update process of the first display unit 81, the controller 10 detects this in step 407 and performs the fourth image data update process of the fourth display unit 83 as shown in FIG. 7C. .

When the image data of the fourth display unit 84 is updated, the controller 10 detects it in step 411 and proceeds to step 413. When the received fourth image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113 in step 413, the memory controller 123 stores the minimum frame image data in the second memory 132. do. In operation 414, the memory controller 123 blocks the fourth image data stored in the second memory 132 into the fourth region 131-3 of the first memory 131 to update the screen of the fourth display unit 84. Proceed to step. When the screen update process of the fourth display unit 84 is completed, the memory controller 123 again performs the screen update process of the first display unit 81 in step 406. When the set time elapses during the screen update process of the first display unit 81, the controller 10 detects this in step 407 and performs the fourth image data update process of the fifth display unit 85 as shown in FIG. 7D. .

When the image data of the fifth display unit 85 is updated, the controller 10 detects this in step 412 and proceeds to step 413. If the received fifth image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113 in step 413, the memory controller 123 stores the minimum frame image data in the second memory 132. do. In operation 414, the memory controller 123 blocks the fifth image data stored in the second memory 132 into the fifth area 131-4 of the first memory 131 to update the screen of the fifth display unit 85. Proceed to step. When the screen update process of the fifth display unit 85 is completed, the memory controller 123 again performs the screen update process of the first display unit 81 in step 406.

Alternatively, in the portable terminal including the image processing unit having two memories as shown in FIG. 6, when the process of updating the received first image signal is performed in step 406, the maximum frame image data received is the second memory. The memory controller 123 transmits the first image data stored in the second memory 132 to the first display unit 81 and displays the image data. Alternatively, when the update signal is received from the controller 10, the memory controller 123 detects this and updates the screen of the first display unit 81 while displaying and transmitting the first image data stored in the second memory 132 to the first display unit 81. 6A illustrates a screen update process of the first display unit.

When the preset time (for example, 1 minute) elapses while updating the first image data as described above, the controller 10 detects this in step 407 and proceeds to step 408. In step 408, the memory controller 123 stops updating the first image data under the control of the controller 10, and outputs and displays the first image data stored in the second memory 132 on the first display unit 81. The update process of the second to fifth image data is performed. First, when updating the image data of the second display unit 82, the control unit 10 detects this in step 409 and proceeds to step 413. If the received second image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113 in step 413, the memory controller 123 stores the minimum frame image data in the second memory 132. do. In operation 414, the memory controller 123 blocks the second image data stored in the second memory 132 to the second area 131-1 of the first memory 131 to update the screen of the second display unit 82. Proceed to step. 6B illustrates a screen update process of the second display unit. When the screen update process of the second display unit 82 is completed, the memory controller 123 again performs the screen update process of the first display unit 81 in step 406. When the set time has elapsed during the screen update process of the first display unit 81, the controller 10 detects it in step 407 and performs the image data update process of the third to fifth display units 83-85. It is the same as the screen update process of the display part 32.

When the plurality of channel screens are updated as described above, and the user scrolls as shown in FIG. 7 while the user views the first display unit 81, the selection cursor of the second display unit a to the fifth display unit d moves. In this case, when the user selects a display unit of a desired channel, the image data of the selected display unit may be output and displayed on the first display unit 81. The channel change process as described above will be described in detail with reference to FIGS. 8 to 11.

8A and 8B are flowcharts illustrating a channel conversion process in a mobile terminal according to an embodiment of the present invention, and FIGS. 9A and 9C illustrate a channel conversion process in a mobile terminal including an image processing unit having three memories. 10A to 10B are views for explaining a channel conversion process in a mobile terminal including an image processing unit having two memories, and FIG. 11 illustrates a process of converting and displaying a channel according to FIG. 8. It is a figure which shows.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1, 2, and 3. In the exemplary embodiment of the present invention, it is assumed that the first video signal is displayed on the first display part 81 and the second- fifth video signal is displayed on the second- fifth display part.

First, as shown in FIG. 9, in operation of displaying a plurality of channels in a portable terminal including an image processing unit having three memories, when the TV key is pressed in a standby state, the controller 10 proceeds to step 801. This is detected and the TV mode is set in step 802. In step 803, the control unit 10 outputs control data for selecting a TV channel, and the TV channel control data is output to the tuner 50 through the control interface 117 and the I ² C master 115. In this case, if a channel is not designated after setting the TV mode, the controller 10 outputs channel control data to access a channel designated in a previous state. The tuner 50 then frequency-converts the first video signal received by being tuned to a designated channel, and the decoder 60 decodes the first video signal into an RGB analog video signal and a synchronization signal and outputs the same. Then, the A / D converter 111 converts the received analog first image signal into digital first image data, and the scaler 113 scales the digital first image data to a maximum frame size (176 * 220 * 12bit). The memory controller 123 stores the user data output from the controller 10 in the memory 131, stores the maximum frame image data in the second memory 132, and transmits the maximum frame image data to the first display unit 81.

The portable terminal is set to the multi-channel view, and the control unit 10 detects it in step 804 and outputs respective control data for tuning the TV channel of the second to fifth video signals, and the TV channel control data It is output to tuner 50 via control interface 117 and I ² C master 115. The tuner 50 then frequency-converts the second to fifth video signals, and the decoder 60 decodes the second to fifth video signals into an RGB analog video signal and a synchronization signal, respectively, and outputs the same. Then, the A / D converter 111 converts the received analog second- fifth image signal into a digital second- fifth image signal, and the scaler 113 converts the digital second- fifth image signal into a minimum frame (75 *). 100 x 12 bits). Then, the memory controller 123 stores the minimum frame image data in the second memory 132 and copies the block to the second to fifth regions 131-1 to 131-4 of the first memory 131 to display the second to fifth displays. Send to 82-85. If the mobile terminal is not set to the multi-channel view, the controller 10 detects this in step 804 and controls the memory controller 123 to transmit and display only the maximum frame image data to the first display unit 81 in step 830.

The memory controller 123 displays the first image data on the first display unit 81 and the second to fifth image data on the second to fifth display units 82 to 85 in step 505 under the control of the controller 10. In this case, the memory controller 123 controls the memory so that the first image signal received in step 806 can be updated and displayed in real time. In the process of updating the received first image signal in step 806, the maximum received frame image data is stored in the second memory 132 (or the third memory 133) and the third memory 133 (or the second memory). The digital image data of the previous maximum frame stored in 132 is output. When outputting image data of one frame is completed, the memory controller 123 outputs user data stored in the memory 131. Thereafter, when the image data of the next maximum frame is received, the memory controller 123 stores the received maximum frame image data in the third memory 133 (or the second memory 132) and simultaneously to the second memory 132 (or the third memory 133). Outputs the digital image data of the previous stored maximum frame. 9A illustrates that the first image data is updated through the second memory 132 and the third memory 133.

The user selects the second display unit 82 as shown in FIG. 11A through the keypad 27 while updating the first image data as described above, and the control unit 10 detects it in step 808 and the first display unit 81 of FIG. Proceed to step 806 to stop the screen update process. When the received first image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 816 of storing the minimum frame image data in the second memory 132. do. In operation 817, the memory controller 123 blocks the first image data stored in the second memory 132 with the minimum frame size in the second area 131-1 of the first memory 131, and then copies the first image data to the second display 82. In step 818, the data is displayed. 9B illustrates a process in which the first image data is displayed on the second display unit. When the received second image data is scaled to the maximum frame size (176 * 220 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 819 of storing the maximum frame image data in the second memory 132. do. The memory controller 123 controls to display the second image data having the maximum frame size stored in the second memory 132 on the first display unit 81 in step 820. 9C illustrates a process in which the second image data is displayed on the first display unit 81. If the second image data is displayed on the first display unit 81 and the first image data is displayed on the second display unit 82 in step 821, the memory controller 123 performs an update process of the second image data in step 806. Done. FIG. 11B illustrates that the second image data is displayed on the first display unit 81 and the first image data is displayed on the second display unit 82. Alternatively, when the user selects the third display unit 83 through the keypad 27 while updating the first image data, the controller 10 detects it in step 810 and stops the screen update process of the first display unit 81 in step 811. Proceed. When the received first image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 816 of storing the minimum frame image data in the second memory 132. do. In operation 817, the memory controller 123 blocks the first image data stored in the second memory 132 at the minimum frame size in the third region 131-2 of the first memory 131, and then copies the first image data to the third display unit 83. In step 818, the data is displayed. When the received third image data is scaled to the maximum frame size (176 * 220 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 819 of storing the maximum frame image data in the second memory 132. do. In operation 820, the memory controller 123 controls the third image data having the maximum frame size stored in the second memory 132 to be displayed on the first display unit 81. If the third image data is displayed on the first display unit 81 and the first image data is displayed on the third display unit 83 in step 822, the memory controller 123 performs an update process of the third image data in step 806. Done. Alternatively, when the user selects the fourth display unit 84 through the keypad 27 while updating the first image data, the controller 10 detects it in step 812 and stops the screen updating process of the first display unit 81 in step 813. Proceed. When the received first image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 816 of storing the minimum frame image data in the second memory 132. do. In operation 817, the memory controller 123 blocks the first image data stored in the second memory 132 with the minimum frame size in the fourth area 131-3 of the first memory 131, and then copies the first image data to the fourth display unit 84. In step 818, the data is displayed. When the received fourth image data is scaled to the maximum frame size (176 * 220 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 819 of storing the maximum frame image data in the second memory 132. do. The memory controller 123 controls to display the fourth image data having the maximum frame size stored in the second memory 132 on the first display unit 81 in step 820. If the fourth image data is displayed on the first display unit 81 and the first image data is displayed on the fourth display unit 84 in step 823, the memory controller 123 performs an update process of the fourth image data in step 806. Done. Alternatively, when the user selects the fifth display unit 85 through the keypad 27 while updating the first image data, the controller 10 detects it in step 814 and stops the screen updating process of the first display unit 81 in step 815. Proceed. When the received first image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 816 of storing the minimum frame image data in the second memory 132. do. In operation 817, the memory controller 123 blocks the first image data stored in the second memory 132 with the minimum frame size in the fifth area 131-4 of the first memory 131, and then, on the fifth display unit 85, the first image is copied. In step 818, the data is displayed. When the received fifth image data is scaled to the maximum frame size (176 * 220 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 819 of storing the maximum frame image data in the second memory 132. do. The memory controller 123 controls to display the fifth image data having the maximum frame size stored in the second memory 132 on the first display unit 81 in step 820. If the fifth image data is displayed on the first display unit 81 and the first image data is displayed on the fifth display unit 85 in step 824, the memory controller 123 performs an update process of the fifth image data in step 806. Done.

As shown in FIG. 10, when the channel is converted in a portable terminal including an image processor having two memories, the first image signal received in step 806 is stored in the second memory 132 at the maximum frame size. When the update signal is received from the controller 10, the memory controller 123 detects this and updates the screen of the first display unit 81 while transmitting the first image data stored in the second memory 132 to the first display unit 81. 10A illustrates a screen update process of the first display unit.

The user selects the second display unit 82 through the keypad 27 while updating the screen of the first display unit as described above, and the controller 10 detects it in step 808 and stops the screen update process of the first display unit 81. Proceed to step. When the received first image data is scaled to the minimum frame size (75 * 100 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 816 of storing the minimum frame image data in the second memory 132. do. In operation 817, the memory controller 123 blocks the first image data stored in the second memory 132 with the minimum frame size in the second area 131-1 of the first memory 131, and then copies the first image data to the second display 82. In step 818, the data is displayed. 10B illustrates a process in which the first image data is displayed on the second display unit. When the received second image data is scaled to the maximum frame size (176 * 220 * 12bits) through the scaler 113, the memory controller 123 proceeds to step 819 of storing the maximum frame image data in the second memory 132. do. The memory controller 123 controls to display the second image data having the maximum frame size stored in the second memory 132 on the first display unit 81 in step 820. 10C illustrates a process in which the second image data is displayed on the first display unit 81. If the second image data is displayed on the first display unit 81 and the first image data is displayed on the second display unit 82 in step 821, the memory controller 123 performs an update process of the second image data in step 806. Done. Alternatively, when the user selects a desired channel from the third to fifth display units 83 to 85 through the keypad 27 while updating the first image data in step 806, the user may select the selected display unit through the above process. Image data may be viewed through the first display unit 81.

   In the above description of the present invention, a specific embodiment such as a portable terminal has been described, but various modifications can 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.

That is, as described above, the present invention has an effect of allowing a user to check and watch a desired channel at a desired time period by simultaneously displaying a plurality of channels on a portable terminal having a television function.

1 is a diagram illustrating a configuration of a portable terminal displaying a television video signal according to an embodiment of the present invention.

FIG. 2 is a diagram showing details of a connection relationship between a control unit and components for receiving a television signal in FIG. 1; FIG.

3 is a diagram illustrating a configuration of an image processor of FIGS. 1 and 2.

4A and 4B are flowcharts illustrating a method of displaying a plurality of channels in a mobile terminal according to an exemplary embodiment of the present invention.

5A and 5B are diagrams for explaining a screen updating process according to a first embodiment of the present invention;

6A and 6B illustrate a screen updating process according to a second embodiment of the present invention.

FIG. 7 is a diagram for explaining FIG. 4. FIG.

8A and 8B are flowcharts illustrating a channel conversion process in a mobile terminal according to an embodiment of the present invention.

9A to 9C are diagrams for explaining a channel conversion process according to the first embodiment of the present invention.

10A to 10C illustrate a channel conversion process according to a second embodiment of the present invention.

FIG. 11 is a view for explaining FIG. 8. FIG.

Claims (13)

An apparatus for displaying at least two television video signals in a portable terminal, A tuner for receiving the television video signal; A decoder which decodes the received composite video signal and generates analog video signals and synchronization signals; An image processing unit converting the analog image signal into digital image data and processing the maximum frame or minimum frame size, and outputting the maximum frame or minimum frame image data in the frame section; And a display unit including a first display unit for displaying the maximum frame image data output from the image processor and a second-nth display unit for displaying the minimum frame image data, respectively. The method of claim 1, wherein the image processing unit, A scaler for scaling the image data to the maximum frame or the minimum frame screen size in synchronization with the synchronization data output from the decoder; A first memory for storing user data and the minimum frame image data; A second memory for storing the maximum frame and minimum frame image data; A third memory for storing the maximum frame image data; Storing the received maximum frame image data in the second memory (or third memory), outputting image data of a previous maximum frame stored in the third memory (or second memory), and receiving the minimum frame image data. And a memory controller configured to store the received minimum frame image data in the second memory and block copy the image data of the minimum frame stored in the second memory into a corresponding region of the first memory. Device. The method of claim 1, wherein the image processing unit, A scaler for scaling the image data to the maximum frame or the minimum frame screen size in synchronization with the synchronization data output from the decoder; A first memory for storing user data and the minimum frame image data; A second memory for storing the maximum frame and minimum frame image data; Storing the received maximum frame image data in the second memory and outputting the maximum frame image data stored in the second memory, and receiving the received minimum frame image data in the second memory. And a memory controller configured to block copy image data of the minimum frame stored in the second memory into a corresponding region of the first memory. The method of claim 2 or 3, wherein the first memory, And the second-nth regions for storing the minimum frame image data. At least two portable terminals including a display unit including a first display unit for displaying the image data of the maximum frame and a second-n-th display unit for displaying the image data of the minimum frame, and an image processing unit including the first to third memories. In the method for displaying television image data, Controlling the tuner in the television mode to receive the first to nth image data; Displaying the first image data on the first display unit and displaying the second-n-th image data on the second-n-th display unit, respectively; Updating the first image data and displaying the first image data on the first display unit; When the predetermined time elapses, updating of the first image data is paused, updating one of the second to n-th image data, and then returning to the updating of the first image data. Said method. The method of claim 5, wherein the displaying of the first-th n-th image data on the first-nth display unit comprises: When the first image data is received, scaling up to the maximum frame image data, storing the image in a second memory, and displaying the same on the first display unit; Receiving the second-n-th image data, scaling to the minimum frame image data, storing the result in the second memory, and copying the block to the second-n-th area of the first memory to display the second-n-th display unit. The method characterized in that. The method of claim 5, wherein the updating of the first image data comprises: Storing the received first image data as the maximum frame image data in the second memory (or the third memory) and outputting the image data of the previous maximum frame being stored in the third memory (or the second memory); Storing the received first image data as the maximum frame image data in the third memory (or the second memory) and outputting the image data of the previous maximum frame stored in the second memory (or the third memory). The method characterized in that. The method of claim 5, wherein the updating of the second to n-th image data comprises: Determining whether a preset time has elapsed, Displaying the first image data stored in the third memory on the first display unit and stopping the update process of the first image data when the set time elapses; Storing image data to be updated among the received second-n-th image data to a minimum frame image data and storing the image data in a second memory; Displaying updated image data by block copying the image data stored in the second memory to a corresponding region of the second to n-th regions of the first memory; And updating the first image data to display on the first display unit and returning to determining whether the set time has elapsed. The method of claim 5, wherein the channel conversion process of the image data, Updating the first image data and displaying the first image data on the first display unit; Stopping updating of the first image data when selecting image data for channel conversion among the second-n-th image data; Scaling the received first image data to minimum frame image data and storing the first image data in a second memory; Block copying and displaying the first image data stored in the second memory in a first memory area of the selected image data; When the selected image data is received, scaling to the maximum frame image data and storing the same in the second memory; Outputting the selected image data stored in the second memory to display on the first display unit; And updating the selected image data through the second memory and the third memory and displaying the selected image data on the first display unit. The method of claim 5, wherein the updating of the first image data when the image processor includes the first-second memory includes: Storing the received first image data in a second memory; And outputting the image data stored in the second memory when the image data is stored in the second memory or the update signal is received. The method of claim 5, wherein updating the second-n-th image data when the image processor includes the first-second memory, Determining whether a preset time has elapsed, When the set time has elapsed, outputting first image data stored in the second memory and displaying the first image data on the first display unit, and pausing the update process of the first image data; Storing the received second-n-th image data to be updated to the minimum frame image data in the second memory; Displaying the updated image data by block copying the image data stored in the second memory to a corresponding region of the second to n-th regions of the first memory; And updating the first image data to display on the first display unit and returning to determining whether the set time has elapsed. The method of claim 5, wherein the channel conversion process of the image data when the image processor includes the first-second memory, Updating the first image data and displaying the first image data on the first display unit; Stopping updating of the first image data when selecting image data for channel conversion among the second-n-th image data; Scaling the received first image data to minimum frame image data and storing the first image data in a second memory; Block copying and displaying the first image data stored in the second memory in a first memory area of the selected image data; When the selected image data is received, scaling to the maximum frame image data and storing the same in the second memory; Outputting the selected image data stored in the second memory to display on the first display unit; And updating and displaying the selected image data through the second memory. At least two portable terminals including a display unit including a first display unit for displaying the image data of the maximum frame and a second-n-th display unit for displaying the image data of the minimum frame, and an image processing unit including the first to third memories. In the method for displaying television image data, Controlling the tuner in the television mode to receive the first to nth image data; Displaying the first image data on the first display unit and displaying the second-n-th image data on the second-n-th display unit, respectively; Updating the first image data and displaying the first image data on the first display unit; Stopping updating of the first image data when selecting image data for channel conversion among the second-n-th image data; Scaling the received first image data to minimum frame image data and storing the first image data in a second memory; Block copying and displaying the first image data stored in the second memory in a first memory area of the selected image data; When the selected image data is received, scaling to the maximum frame image data and storing the same in the second memory; Outputting the selected image data stored in the second memory to display on the first display unit; And updating the selected image data and displaying the first image on the first display unit.