KR100563738B1 - mobile terminal capable of reproducing television signal - Google Patents

Abstract

The present invention relates to a mobile communication terminal capable of receiving a television signal.

The mobile communication terminal according to the present invention includes a TV receiver for reconstructing and reproducing an image signal from a TV signal, and time-dividing the TV receiver to obtain two channel images. The acquired channel image is processed by the signal processor and partitioned on one screen or displayed in picture-in-picture form.

According to the present invention, it is possible to simultaneously view two channels with a single tuner, which makes the configuration of the terminal compact and reduces the manufacturing cost.

Mobile Phone, Mobile Communication, Camera, TV, Television, Bus, LCD, Channel

Description

Mobile terminal capable of reproducing television signal

1 is a block diagram schematically showing the configuration of a mobile communication terminal according to an embodiment of the present invention.

2 is a block diagram illustrating in detail a possible embodiment of the terminal shown in FIG.

3 is a block diagram illustrating in detail another possible embodiment of the terminal shown in FIG.

4 illustrates an embodiment of the tuner unit of FIGS. 2 and 3.

5 is a flowchart schematically illustrating a control method of the embodiment illustrated in FIG. 2.

6 is a flowchart schematically illustrating a control method of the embodiment illustrated in FIG. 3.

<Description of Symbols for Main Parts of Drawings>

100: control unit 110: communication control unit

130: system control unit 210: voice input and output circuit

220: audio output unit 230: wireless communication unit

250: keypad 271: display driver

273: display unit 300: signal processing unit

310: control unit 330: image processing unit

331: scaling unit 333: image synthesizing unit

335: signal processor 339: frame memory

370: video output unit 353: bus interface unit

355: media interface unit

700: TV receiver 710: tuner unit

730: decoder 750: TV control unit

773: bus interface unit

The present invention relates to a mobile communication terminal, and more particularly to a mobile communication terminal capable of receiving a television signal.

As the spread of mobile communication terminals is rapidly increasing, various functions are being added every day due to consumer demand and competition among companies. Accordingly, terminals are evolving into integrated multimedia devices with large amounts of memory.

In the case of TV phones, a compact tuner with sufficient performance has not yet been provided, so it is very difficult to maintain the existing compact size when implemented in a mobile communication terminal. Most televisions support Picture-In-Picture (PIP), allowing viewers to watch different channels on the sub-screen while watching the main screen. However, two tuners are required to support this PIP function. Including two tuners in a TV phone is not practical because of the characteristics of a portable terminal that must be compact in a situation where not only the manufacturing cost but also the size of the tuner is a problem.

But users want this feature to be supported on TV phones. Therefore, there is a need for a TV phone capable of watching two channels simultaneously without incurring additional cost or additional space for components.

On the other hand, in a terminal with emphasis on portability, implementing such a function requires not only a physical problem of securing a necessary space in the terminal but also an efficient architecture for proper control between systems. Moreover, designing a new system architecture every time has been very inefficient in terms of cost and time due to the frequently added features.

SUMMARY OF THE INVENTION The present invention is derived from this background, and an object thereof is to provide a mobile communication terminal capable of simultaneously reproducing television signals of two channels without incurring additional cost or additional space for components.

In addition, an object of the present invention is to provide a mobile communication terminal capable of reproducing a television signal that enables a user to easily switch between a main channel and a subchannel.

Furthermore, an object of the present invention is to provide a unified and systematic control between modules in a terminal and to provide a system architecture that is easy to design when adding a new functional module.

According to an aspect of the present invention, a mobile communication terminal provides a voice call through a mobile communication network, and additionally displays video signals of two channels restored by time-division tuning of a wireless television signal on one screen. It is characterized by playing on.

According to this aspect of the present invention, the mobile communication terminal according to the present invention is capable of reproducing television signals of two channels with only a single tuner.

The mobile communication terminal according to an additional aspect of the present invention scales the video signal of the first channel and the second channel, which are time-division tuned and reconstructed, respectively, and then outputs the synthesized one screen.

According to another aspect of the present invention, the mobile communication terminal is time-division tuned and reconstructed, and the video signal of the first channel of the two channel video signals is restored to the first area of the screen, and the video signal of the second channel of the screen Output to area 2. In this case, since the display unit updates only one video signal region at each point in time, data output to the display unit can be minimized. This makes it possible to save resources necessary for driving the display.

The mobile communication terminal according to the supplementary aspect of the present invention can display the currently playing channels on the main screen and the sub-screen by swapping with each other according to an operation command from the keypad.

According to this aspect of the present invention, the mobile communication terminal according to the present invention has an advantage that the user can operate it very simply when the user wants to switch to the sub-screen channel.

According to a further aspect of the present invention, the controller is characterized in that for controlling the operation of the TV receiver and the signal processor using a serial bus.

According to this aspect of the present invention, in a modern terminal including a plurality of modules, such as a camera module, a ringtone reproduction module, for example, it is possible to uniformly control the modules constituting the entire system, and furthermore, when adding a new module. The hardware design is very simple by simply incorporating on the bus, and in addition, it is possible to present a standard basic structure in software design.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

1 is a block diagram schematically showing the configuration of a mobile communication terminal according to an embodiment of the present invention. As shown, the mobile communication terminal according to the present exemplary embodiment includes a control unit 100 and its subcircuits, a TV receiver 700 and a signal processor 300, which are largely common to existing mobile communication terminals. do.

The accessory circuits include a keypad 250, a display unit 273 for displaying menus and operating states, a wireless communication unit 230 for extracting voice and data signals from a wireless signal transmitted and received through an antenna, and a voice call signal from the wireless communication unit. It includes a voice input and output circuit 210 for inputting and outputting through a microphone and a speaker.

The keypad 250 is a means for receiving a normal operation command. For example, in the case of a clamshell terminal, the display unit 273 is a relatively large liquid crystal display unit formed inside the folder. The display portion 273 is driven by the display driver 271. In some cases, the display unit is sometimes used to mean the display unit 273 and the display driver 271. The wireless communication unit 230 includes an antenna and an RF circuit for communication with the base station. In the present specification, the wireless communication unit is interpreted to cover not only various versions of CDMA but also existing methods such as cellular, GSM, and W-CDMA, as well as mobile communication. The voice input / output circuit 210 processes a conversion of digital voice data into an analog voice signal or vice versa, and has a known configuration including an additional circuit such as an audio amplification circuit or a filter.

The baseband circuit of the wireless communication unit 230 and most of the circuits of the control unit 100 are commercially provided as a single integrated circuit. This integrated circuit, commonly referred to as an MSM chip, includes internally dedicated hardware for processing communications, a digital signal processor and a general purpose microprocessor. Logically, the controller 100 includes a communication processor 110 for controlling voice and data communication, and a system controller 130 for controlling the entire system according to an operation signal or an operation state input from a keypad.

According to a characteristic aspect of the present invention, the mobile communication terminal reproduces the video signals of the two channels restored by time division tuning of the wireless television signal on the display unit 273 as one screen. In a preferred embodiment, the mobile communication terminal includes a TV receiver 700 for receiving a wireless television signal and restoring the video signal. The system controller 130 of the controller 100 controls time-division control of the TV receiver 700 according to an operation command from the keypad 250 to output video signals of two different channels. In the present exemplary embodiment, the video signals of two different channels output by the TV receiver 700 are composed of one screen signal from the signal processor 300 and output to the display driver 271. At this time, the video signal transmitted between the TV receiver 700 and the signal processor 300 is a standard YUV 8-bit format. The display driver 271 outputs the input video signal as visible information.

In one embodiment, the signal processing unit 300 configures and outputs the image signals of the two channels output from the TV receiver 700 as picture signals in a picture-in-picture form. In another exemplary embodiment, the signal processor 300 may split up and down two image signals of two channels output from the TV receiver 700. In this case, in the case of the divided screen, it is preferable to time-division tune the two screens at the same time interval so that both upper and lower channels are displayed at the same frame rate. However, the present invention is not limited thereto, and is intended to cover various modifications including, for example, dividing the screen into four parts to time-division tune the TV receiver 700 at the same time interval to display four channels.

 In addition, the audio signal of the demodulated signal in the TV receiver 700 may be directly output from the audio output unit 220. The audio output unit 220 selectively or mixes and outputs various audio sounds output from the terminal such as a ringtone reproduction sound and a sound source reproduction sound.

2 is a block diagram illustrating in detail a possible embodiment of the terminal shown in FIG. As shown, in the present embodiment, the TV receiver 700 includes a tuner unit 710 for demodulating a radio broadcast signal received from an antenna, and a decoder unit 730 for decoding and demodulating the demodulated broadcast signal as digital data. And a TV control unit 750 for controlling an operation according to a control command signal from the outside. The TV receiver 700 includes an antenna for receiving an air wave signal. This antenna may exist separately from the antenna for mobile communication, or in the case of a strip patch antenna type, may be physically shared as one antenna.

The tuner unit 710 may be one of the existing analog broadcast tuners such as NTSC and PAL, or a common tuner that supports all of them. In another embodiment, the tuner 710 may be a mobile communication multimedia broadcast such as a digital multimedia broadcasting (DMB) scheme for receiving satellite broadcasts or a multimedia broadcast based on a wireless LAN.

4 illustrates one embodiment of a tuner portion 710. The radio broadcast signal received from the antenna passes through the UHF filter 711 and the VHF filter 712, and is separated into a signal of the UHF band and a signal of the VHF band, respectively. Signals in each band are filtered through their respective Low Noise Amplifiers (713, 714). The filtered signal is supplied to the PLL IC 717, mixed with the local oscillation frequency, and demodulated in one step. In this case, the intermediate frequency for each signal is supplied from voltage controlled oscillators 715 and 716 for each band. The oscillation frequencies of these oscillators are controlled by the TV control unit 750 of FIG. 2 which controls channel tuning. The first demodulated signal is second demodulated by an IF (Intermediate Frequency) signal processor 725 and output to the decoder 730 and the audio output unit 220 as analog video and audio signals, respectively. At this time, the tuner 710 and the IF signal processor are controlled by the TV controller 750 of FIG. 2 to control channel tuning. In addition, the output level of the audio output unit 220, that is, the volume is also controlled by the TV control unit 750 of FIG.

In the present exemplary embodiment, the tuner 710 of the TV receiver 700 is tuned to the main picture channel for 24 frame periods out of 30 frames per second output from the display unit 273, and the sub picture channel for 6 frame periods. Tuned into However, the channel is not continuously tuned to the main picture channel for 24 frame periods, but is tuned to the main picture channel for 4 frame periods, and to the sub picture channel for 1 frame period. Accordingly, frames of the sub picture channel are secured every 1/6 second.

In one embodiment, the decoder 730 generates and outputs a digital YUV signal from the analog video output of the video output unit 726. The operation of the decoder unit is controlled by the TV control unit 750.

The signal processor 300 was originally developed by the present applicant for signal processing of a camera phone, and according to the characteristic structure of the present invention, the signal processor 300 may be applied to the TV receiver 700 as it is, or on a conventional camera phone. Despite the addition of the receiver 700, it can be adopted as it is without any special structural changes. In addition, it is a characteristic advantage of the present invention that the existing signal processing unit 300 for the camera module can be used in common without adding a separate signal processing module for the TV receiving unit 700. In this case, the signal processor 300 may alternatively process one of the first image signal output from the camera module and the second image signal output from the TV receiver 700 and output the same to the display unit 273.

In an exemplary embodiment, the signal processor 300 may include a media interface 355 that receives an image signal output from the TV receiver, and a video signal of a first channel among the Youngshin signals input from the media interface 355. An image processor 330 for scaling and then synthesizing the image signals of the second channel, and an image output unit for converting the image signal processed by the image processor 330 into display data and outputting the image data to the display driver 271 ( 370 and a signal processing controller 310 for controlling the operation according to a control command signal from the outside.

The media interface unit 355 receives 8-bit image data in YUV format and buffers it in the internal memory. The image processor 330 converts the TV signal of the parallel scan type into a sequential scan method, and scales the interpolated and / or decimation processes to match the resolution of the display device.

In one embodiment, the scaling unit 331 of the image processing unit 330 converts the input television signal into a sequential scanning method, and the size suitable for the resolution of the entire display unit 273 for the frame of the timing to be displayed on the main screen To scale. In this case, if the resolution of the display unit 273 is appropriate, 1: 1 scaling, that is, separate scaling may not be necessary. On the other hand, the scaling unit 331 scales the frame of the timing to be displayed on the sub-screen so as to fit the size of the lower right quarter of the display unit 273, for example. In the present embodiment, since the display unit 273 matches the frame resolution of the standard NTSC system, the sub-screen frames are scaled by the scaling unit 331 at a quarter rate.

The scaled images are synthesized by the image synthesizer 333. As described above, in the present embodiment, the TV receiving unit 700 is tuned to the main picture channel for 24 frame periods out of 30 frames per second output from the display unit 273, and to the sub picture channel for 6 frame periods. do. However, the channel is not continuously tuned to the main picture channel for 24 frame periods, but is tuned to the main picture channel for 4 frame periods, and to the sub picture channel for 1 frame period. Accordingly, frames of the sub picture channel are secured every 1/6 second. The image synthesizing unit 333 secures the main picture channel layer and the sub picture channel layer space in the frame memory 339, writes the main picture channel frames four times in the main picture channel layer area, and then writes one to the next sub picture channel layer area. Record times. Images recorded in each layer are synthesized by the image synthesizer 333 and output to the image quality improving unit 335 at 30 frames per second.

In one embodiment, the image synthesizing unit 333 of the signal processing unit 300 is a picture signal in the picture-in-picture form of the video signals of the two channels output from the TV receiver 700 Configured and output. In another exemplary embodiment, the image synthesizing unit 333 may divide the image signals of the two channels output from the TV receiving unit 700 by splitting them up and down. In this case, in the case of the divided screen, it is preferable to time-division tune the two screens at the same time interval so that the upper and lower channels are displayed at the same frame rate. However, the present invention is not limited thereto, and is intended to cover various modifications including, for example, dividing the screen into four parts to time-division tune the TV receiver 700 at the same time interval to display four channels.

 The image quality improvement unit 335 may include a sharpness enhancement process for improving image quality, and a contrast and contrast adjustment function. You can even include some simple filter functions to give you graphical effects. The image processing of the image quality improving unit 335 may be applied before the scaling unit 331 or applied between the scaling unit 331 and the image combining unit 333.

In the present embodiment, the image output unit 370 converts the image data output from the image processing unit 330 into a 16-bit RGB data format supported by the display unit 270 that is typically a liquid crystal screen.

According to a characteristic aspect of the present invention, the system control unit 130 of the control unit 100 receives an operation command from the user from the keypad 250 and accordingly in the terminal including the signal processing unit 300 and the TV receiving unit 700 Control each part. The system controller 130 controls the tuner 710 of the TV receiver 700 to be tuned to the first channel for the first four frame periods, and displays the output image signal of the first channel as the main screen on the display unit 273. The signal processor 300 is controlled so that the tuner 710 of the TV receiver 700 is tuned to the second channel for the next one frame period, and the video signal of the second channel output from the TV receiver 700 is tuned to the display unit 273. The signal processor 300 is controlled to display the screen.

According to a characteristic aspect of the present invention, the TV receiver 700 operates according to a bus interface unit 770 for receiving a serial bus control signal from the signal processor 300 and a control signal received from the bus interface unit 770. TV control unit 750 to control the.

According to a characteristic aspect of the present invention, the signal processing unit receives a video signal input from the TV receiving unit 700 and the media interface unit 355, and receives a control signal from the outside in the slave mode or controls the outside from the host mode. A bus processing unit 353 for outputting a signal and a signal processing control unit for controlling the overall signal processing unit 300 or an external module through the bus interface unit 353 according to a control signal input from the bus interface unit 353. 310.

According to another characteristic aspect, the controller 100 controls the operation of the TV receiver 700 and the signal processor 300 using a serial bus. In one embodiment, the serial bus is an I ² C bus. Also called Inter-IC, I ² C is a two-wire, bidirectional serial bus that provides a communication link between integrated circuits. Philips introduced the I ² C bus 20 years ago for mass production products such as TVs, VCRs and audio equipment.

In the present embodiment, the control unit 100 transmits a control command to the signal processing unit 300, and the control of the TV receiving unit 700 is performed by the signal processing control unit 310 of the signal processing unit 300. Therefore, the bus interface 353 of the signal processor 300 operates in the slave mode when receiving the control command from the controller 100, and operates in the host mode when transmitting the control command to the TV receiver 700. As a result, the design difficulty of the controller 100 in charge of complex control of the entire terminal can be reduced, and efficient allocation of resources can be achieved.

At this time, the signal processing control unit 310 of the signal processing unit 300 separately controls the volume of the tuner unit 710 and the decoder unit 730 of the TV receiver 700, and additionally, the audio output unit 220 by assigning a plurality of addresses. The bus interface unit 353 is controlled to be accessed. The signal processing control unit 310 may control an operation of changing the TV channel, adjusting the volume, or changing the format of the output image by recording control commands to these addresses through the bus interface unit 353. . According to a characteristic aspect of the present invention, the signal processing controller 310 acquires video signals of two channels by synchronously controlling the TV receiver 700 by time division through this bus. When the signal processing unit 300 selects the TV receiving unit 700 by the chip select logic, the signal processing control unit 310 of the signal processing unit 300 sets an operating environment of these modules through the bus interface unit 353 or During operation, the operation of each module is controlled through the bus interface 353.

Hereinafter, the operation of the signal processor 300 according to the characteristic aspect of the present invention will be described in more detail. FIG. 5 is a flowchart schematically illustrating a control flow for reproducing a plurality of channels in the terminal illustrated in FIG. 2.

When the TV viewing is selected by the user first and then the PIP mode is selected, and then the channels to be watched on the main screen and the sub-screen are selected, the system controller 130 transmits the corresponding channel in the corresponding mode to the signal processor 300 through the I ² C bus. Instructs playback into the field. The bus interface unit 353 of the signal processing unit 300 receives this, and the signal processing control unit 310 interprets this command and performs necessary control. Accordingly, the operations of the TV receiver 700 and the image processor 330 are determined.

First, the signal processing controller 310 switches the bus interface 353 from the I ² C slave mode to the I ² C host mode, and then instructs the TV receiver 700 to tune to the channel to be displayed on the main screen. The bus interface unit 770 of the TV receiving unit 700 receives this command, and the TV control unit 750 interprets the command and the voltage controlled oscillators 715 and 716 and the intermediate frequency signal processing unit of the tuner unit 710. 725, etc. to control and demodulate the TV broadcast signal in the corresponding channel (step S110). The demodulated video signal is decoded by the decoder 730 and converted into a digital YUV signal.

This signal is input to the media interface unit 355 of the signal processing unit 300 via the bus. The image processing unit 330 converts the input-parallel scanning image signal under the control of the signal processing control unit 310 into a sequential scanning method image signal and then matches the resolution of the display unit 273, that is, the main screen output form. The interpolation is performed through interpolation / decimation processing (step S120). In this embodiment, the scaling ratio is 1: 1. The scaled image is stored in the main screen layer area of the frame memory 339 (step S120).

Next, the signal processing controller 310 checks the frame counter to check whether the current frame is every fifth frame (step S130). If it is the fifth frame, it is time to acquire the sub-screen image, and the signal processing controller 310 commands the TV receiver 700 to tune to the channel to be displayed on the sub-screen through the bus interface 353. The bus interface unit 770 of the TV receiving unit 700 receives this command, and the TV control unit 750 interprets the command and the voltage controlled oscillators 715 and 716 and the intermediate frequency signal processing unit of the tuner unit 710. 725, etc. to control and demodulate the TV broadcast signal in the corresponding channel (step S140). The demodulated video signal is decoded by the decoder 730 and converted into a digital YUV signal.

This signal is input to the media interface unit 355 of the signal processing unit 300 via the bus. The image processing unit 330 converts the input-parallel scanning image signal under the control of the signal processing control unit 310 into a sequential scanning method image signal, and interpolates the sub-screen output form to match the resolution of the sub-screen. It scales through an interpolation / decimation process (step S150). In this embodiment, the scaling ratio is 1/4. The scaled image is stored in the sub picture layer area of the frame memory 339 (step S150).

If it is not every fifth frame in step 130, that is, it is not the timing to acquire the sub picture channel image, steps S140 and S150, which are processes for obtaining the sub picture channel image, are skipped.

Thereafter, the image synthesizer 333 synthesizes the main screen and the sub-screen images stored in the frame memory 339 (step S160). The synthesized image is output after being selectively processed by the image quality improvement unit 335, such as brightness control, contrast control, image quality improvement, and supplied to the image output unit 370. The image output unit 370 converts the input image signal into a 16-bit RGB image signal, which is a format received from the sub display unit 277, and supplies the converted image signal to the sub display unit 277. The display driver 273 is provided with a display memory, and the image output unit 370 processes the image display by sequentially writing the display data into this memory via a 16-bit parallel bus (step S160).

According to a characteristic aspect of the present invention, the control unit 100 further controls the signal processing unit 300 to alternately display channels currently being reproduced on the main screen and the sub-screen according to an operation command from the keypad 250. Characterized in that it further comprises a switching unit (not shown). At this time, the operation command is preferably input by a single hot key. When the control command is transmitted from the reproduction switching unit, the signal processing control unit 310 of the signal processing unit 300 controls the TV receiving unit 700 to change the channels for the main picture and the sub picture in software.

3 is a block diagram illustrating in detail another possible embodiment of the terminal shown in FIG. As shown, the mobile communication terminal according to the present embodiment time-division-controls the tuning of the TV receiving unit 750 and the TV receiving unit 750 for receiving a wireless television signal and restoring it to a video signal. The video signal of the first channel is output to the first area of the screen and the video signal of the second channel is output to the second area of the screen. And a display unit 271 and 273 configured to configure the image signals output from the signal processor 300 into one screen and output the visual information as visible information.

In the present embodiment, since the TV receiving unit 700 is the same as in the first embodiment, detailed description thereof will be omitted.

In an exemplary embodiment, the signal processor 300 may include a media interface 355 that receives an image signal output from the TV receiver 700, and a first channel of the image signals input from the media interface 355. An image processor 330 for scaling and outputting a video signal of a second channel and a video signal of a second channel, respectively, and converting the image signals processed by the image processor 330 into display data and outputting them to different areas of the display units 271 and 273. And an image output unit 370.

The media interface unit 355 receives 8-bit image data in YUV format and buffers it in the internal memory. The image processor 330 converts the TV signal of the parallel scan type into a sequential scan method, and scales the interpolated and / or decimation processes to match the resolution of the display device.

In one embodiment, the scaling unit 331 of the image processing unit 330 converts the input television signal into a sequential scanning method, and the size suitable for the resolution of the entire display unit 273 for the frame of the timing to be displayed on the main screen To scale. In this case, if the resolution of the display unit 273 is appropriate, 1: 1 scaling, that is, separate scaling may not be necessary. On the other hand, the scaling unit 331 scales the frame at the timing to be displayed on the sub-screen so as to fit the size of the lower right quarter of the display unit 273, for example. In the present embodiment, since the display unit 273 matches the frame resolution of the standard NTSC system, the sub-screen frames are scaled by the scaling unit 331 at a quarter rate.

Similarly to the first embodiment, also in this embodiment, the TV receiver 700 is tuned to the main picture channel for 24 frame periods out of 30 frames per second output from the display unit 273, and for 6 frame periods. Tuned to sub picture channel. This is accomplished by six repetitions of tuning to the main picture channel for four frame periods and tuning to the sub picture channel for one frame period. Accordingly, frames of the sub picture channel are secured every 1/6 second.

In one embodiment, the image quality improvement unit 335 may include a sharpness enhancement process for improving image quality, and a contrast and contrast adjustment function. You can even include some simple filter functions to give you graphical effects. The image processing of the image quality improvement unit 335 may be applied before the scaling unit 331.

In the present embodiment, the image output unit 370 converts the image data output from the image processing unit 330 into a 16-bit RGB data format supported by the display unit 270 that is typically a liquid crystal screen. However, in the present exemplary embodiment, the image output unit 370 outputs image signals of different channels processed by the image processor 330 to different regions of the display unit. In this case, the output video signals are synthesized in a frame memory (not shown) provided in the display driver 271. The video signal of the main picture channel is recorded in the main picture area of this frame memory, and the video signal of the sub picture channel is recorded only in the sub picture area of this frame memory. Accordingly, the image output unit 370 outputs an image signal only to the main screen region during the main screen tuning period, and the image output unit 370 outputs an image signal only to the sub-screen region during the main screen tuning period. As a result, the overall processing can be simplified, and the time required for the image output unit 370 to output an image can be reduced.

The image output unit 370 outputs the image signals of the two channels output from the image processor 330 to be configured as a picture signal in a picture-in-picture form on the display unit 273. In another exemplary embodiment, the image output unit 370 may record the image signals of the two channels output from the image processor 330 to the display driver 271 so that the display unit 273 divides the image signals of the two channels up and down. It may be. In this case, in the case of the divided screen, it is preferable to time-division tune the two screens at the same time interval so that both upper and lower channels are displayed at the same frame rate. However, the present invention is not limited thereto, and is intended to cover various modifications including, for example, dividing the screen into four parts to time-division tune the TV receiver 700 at the same time interval to display four channels.

According to a characteristic aspect of the present invention, the system control unit 130 of the control unit 100 receives an operation command from the user from the keypad 250 and accordingly in the terminal including the signal processing unit 300 and the TV receiving unit 700 Control each part. The system controller 130 controls the tuner 710 of the TV receiver 700 to be tuned to the first channel for the first four frame periods, and displays the output image signal of the first channel as the main screen on the display unit 273. The signal processor 300 is controlled so that the tuner 710 of the TV receiver 700 is tuned to the second channel for the next one frame period, and the video signal of the second channel output from the TV receiver 700 is tuned to the display unit 273. The signal processor 300 is controlled to display the screen.

According to a characteristic aspect of the present invention, the TV receiver 700 operates according to a bus interface unit 770 for receiving a serial bus control signal from the signal processor 300 and a control signal received from the bus interface unit 770. TV control unit 750 to control the.

According to a characteristic aspect of the present invention, the signal processing unit receives a video signal input from the TV receiving unit 700 and the media interface unit 355, and receives a control signal from the outside in the slave mode or controls the outside from the host mode. A bus processing unit 353 for outputting a signal and a signal processing control unit for controlling the overall signal processing unit 300 or an external module through the bus interface unit 353 according to a control signal input from the bus interface unit 353. 310.

According to another characteristic aspect, the controller 100 controls the operation of the TV receiver 700 and the signal processor 300 using a serial bus. In one embodiment, the serial bus is an I ² C bus. In the present embodiment, the control unit 100 transmits a control command to the signal processing unit 300, and the control of the TV receiving unit 700 is performed by the signal processing control unit 310 of the signal processing unit 300. Accordingly, the bus interface 353 of the signal processor 300 operates in the slave mode when receiving the control command from the controller 100, and operates in the host mode when transmitting the control command to the TV receiver 700. As a result, the design difficulty of the controller 100 in charge of complex control of the entire terminal can be reduced, and efficient allocation of resources can be achieved.

At this time, the signal processing control unit 310 of the signal processing unit 300 separately controls the volume of the tuner unit 710 and the decoder unit 730 of the TV receiver 700, and additionally, the audio output unit 220 by assigning a plurality of addresses. The bus interface unit 353 is controlled to be accessed. The signal processing control unit 310 may control an operation of changing the TV channel, adjusting the volume, or changing the format of the output image by recording control commands to these addresses through the bus interface unit 353. . According to a characteristic aspect of the present invention, the signal processing controller 310 acquires video signals of two channels by synchronously controlling the TV receiver 700 by time division through this bus. When the signal processing unit 300 selects the TV receiving unit 700 by the chip select logic, the signal processing control unit 310 of the signal processing unit 300 sets an operating environment of these modules through the bus interface unit 353 or During operation, the operation of each module is controlled through the bus interface 353.

Hereinafter, the operation of the signal processor 300 according to the characteristic aspect of the present invention will be described in more detail. FIG. 6 is a flowchart schematically illustrating a control flow for reproducing a plurality of channels in the terminal illustrated in FIG. 3.

When the TV viewing is selected by the user first and then the PIP mode is selected, and then the channels to be watched on the main screen and the sub-screen are selected, the system controller 130 transmits the corresponding channel in the corresponding mode to the signal processor 300 through the I ² C bus. Instructs playback into the field. The bus interface unit 353 of the signal processing unit 300 receives this, and the signal processing control unit 310 interprets this command and performs necessary control. Accordingly, the operations of the TV receiver 700 and the image processor 330 are determined.

First, the signal processing controller 310 switches the bus interface 353 from the I ² C slave mode to the I ² C host mode, and then instructs the TV receiver 700 to tune to the channel to be displayed on the main screen. The bus interface unit 770 of the TV receiving unit 700 receives this command, and the TV control unit 750 interprets the command and the voltage controlled oscillators 715 and 716 and the intermediate frequency signal processing unit of the tuner unit 710. 725, etc. to control and demodulate the TV broadcast signal in the corresponding channel (step S110). The demodulated video signal is decoded by the decoder 730 and converted into a digital YUV signal.

This signal is input to the media interface unit 355 of the signal processing unit 300 via the bus. The image processing unit 330 converts the input-parallel scanning image signal under the control of the signal processing control unit 310 into a sequential scanning method image signal and then matches the resolution of the display unit 273, that is, the main screen output form. Scale through interpolation / decimation process. In this embodiment, the scaling ratio is 1: 1. The scaled image is optionally processed by the signal processor 335 and then output from the image output unit 370 to the main screen region of the frame memory of the display driver 271 (step S120).

Next, the signal processing controller 310 checks the frame counter to check whether the current frame is every fifth frame (step S130). If it is the fifth frame, it is time to acquire the sub-screen image, and the signal processing controller 310 commands the TV receiver 700 to tune to the channel to be displayed on the sub-screen through the bus interface 353. The bus interface unit 770 of the TV receiving unit 700 receives this command, and the TV control unit 750 interprets the command and the voltage controlled oscillators 715 and 716 and the intermediate frequency signal processing unit of the tuner unit 710. 725, etc. to control and demodulate the TV broadcast signal in the corresponding channel (step S140). The demodulated video signal is decoded by the decoder 730 and converted into a digital YUV signal.

This signal is input to the media interface unit 355 of the signal processing unit 300 via the bus. The image processing unit 330 converts the input-parallel scanning image signal under the control of the signal processing control unit 310 into a sequential scanning method image signal, and interpolates the sub-screen output form to match the resolution of the sub-screen. scaling through an interpolation / decimation process. In this embodiment, the scaling ratio is 1/4. The scaled image is selectively processed by the signal processor 335 and then output from the image output unit 370 to the main screen region of the frame memory of the display driver 271 (step S150).

If it is not every fifth frame in step S130, that is, when it is not the timing to acquire the sub picture channel image, steps S140 and S150, which are processes for obtaining the sub picture channel image, are skipped.

Thereafter, the display driver 271 displays the frame memory stored by combining the main screen and the sub-screen area as a whole, and as a result, images are synthesized and displayed.

According to a characteristic aspect of the present invention, the control unit 100 further controls the signal processing unit 300 to alternately display channels currently being reproduced on the main screen and the sub-screen according to an operation command from the keypad 250. It characterized in that it further comprises a regeneration switch (not shown). At this time, the operation command is preferably input by a single hot key. When the control command is transmitted from the reproduction switching unit, the signal processing control unit 310 of the signal processing unit 300 controls the TV receiving unit 700 to change the channels for the main picture and the sub picture in software.

As described in detail above, the mobile communication terminal according to the present invention can watch different channels by dividing one screen in the mobile communication terminal capable of receiving TV.

Furthermore, according to an aspect of the present invention, the mobile communication terminal can watch different channels on the main screen and the sub-screen with only a single tuner, thereby reducing the manufacturing cost by reducing the terminal hardware, and also taking up less space. There is an advantage.

Furthermore, the mobile communication terminal according to the present invention changes the channels being played on the main screen and the channels being played on the sub screen by hot keys or simultaneously displays the images acquired by receiving them on the display unit and the sub-display unit so that two people face each other simultaneously. There is a very convenient advantage to the user in that it can enjoy.

Furthermore, the mobile communication terminal according to the present invention has a bus for controlling the operation separately from the image processing path, and thus can control the complicated modules uniformly, so that system design, function addition, and design change can be easily performed.                     

The present invention has been described above with reference to preferred embodiments, but is not limited thereto, and is interpreted by the appended claims, which are intended to cover many variations that will be apparent to those skilled in the art without departing from the scope of the present invention. Should be done.

Claims (21)

delete A keypad; A TV receiver for receiving a wireless television signal and restoring the video signal; A control unit controlling time-division control of the TV receiving unit according to an operation command from the keypad to output video signals of two different channels; A signal processor configured to output video signals of two different channels output by the TV receiver as one screen signal; A display unit which outputs a screen signal input from the signal processor as visible information; Mobile communication terminal comprising a. The apparatus of claim 2, wherein the TV receiver comprises: A tuner unit for demodulating the radio broadcast signal received from the antenna, a decoder unit for decoding the demodulated broadcast signal, converting the demodulated broadcast signal into digital data, and outputting the converted signal to the signal processing unit; And a TV control unit for controlling the mobile communication terminal. The mobile communication terminal of claim 3, wherein the tuner unit supports one of NTSC and PAL, or both. The mobile communication terminal of claim 3, wherein the tuner unit is a DMB system. The method of claim 2, wherein the signal processing unit: A media interface unit for receiving the video signal output from the TV receiver and a video signal of the first channel and the video signal of the second channel among the video signals input from the media interface unit, respectively, and then synthesized and output And a video output unit for converting the video signal processed by the video processor into display data and outputting the converted video data to the display unit. 7. The image processing unit of claim 6, wherein the image processing unit of the signal processing unit configures and outputs image signals of two different channels output by the TV receiving unit as picture signals in picture-in-picture form. Mobile communication terminal. 10. The apparatus of claim 7, wherein the control unit further controls a playback switching unit to control the signal processing unit to alternately display a channel currently being played on a main picture and a sub picture of a picture-in-picture according to an operation command from the keypad. Mobile communication terminal comprising a. The mobile communication terminal of claim 8, wherein the operation command is input by a single hot key. The mobile communication terminal of claim 2, wherein the controller controls an operation of the TV receiver and the signal processor by using a serial bus. 12. The mobile terminal of claim 10, wherein the serial bus is an I ² C bus. A TV receiver for receiving a wireless television signal and restoring the video signal; A control unit for controlling time-division control of the TV receiver to output video signals of two different channels; A signal processor for outputting a video signal of a first channel to a first area of a screen and a video signal of a second channel to a second area of a screen;  A display unit configured to output image information output from the signal processing unit as a single screen; Mobile communication terminal comprising a. The method of claim 12, wherein the TV receiving unit: A tuner unit for demodulating the radio broadcast signal received from the antenna, a decoder unit for decoding the demodulated broadcast signal, converting the demodulated broadcast signal into digital data, and outputting the converted signal to the signal processing unit; And a TV control unit for controlling the mobile communication terminal. The mobile communication terminal of claim 13, wherein the tuner unit supports one of NTSC and PAL, or both. The mobile communication terminal of claim 13, wherein the tuner unit is a DMB system. The method of claim 12, wherein the signal processing unit: A media interface for receiving an image signal output from the TV receiving unit, an image processor for scaling out and outputting a video signal of a first channel and a video signal of a second channel among video signals input from the media interface unit; And an image output unit for converting the image signals processed by the zero wound unit into display data and outputting the converted image data to different areas of the display unit. The image processing unit of claim 16, wherein the image processing unit of the signal processing unit is one of two different channel image signals output by the TV receiving unit as a main screen of a picture-in-picture screen. The mobile communication terminal, characterized in that for outputting to the sub-screen area. 18. The apparatus of claim 17, wherein the controller is further configured to control the signal processor to alternately display channels currently being reproduced on the main picture and the sub picture of the picture-in-picture according to an operation command from the keypad. Mobile communication terminal comprising a. 19. The mobile communication terminal according to claim 18, wherein the operation command is input by a single hot key. The mobile communication terminal of claim 12, wherein the controller controls an operation of the TV receiver and the signal processor by using a serial bus. The mobile terminal of claim 20, wherein the serial bus is an I ² C bus.

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