KR19990039446A - Picture-in-Picture Display Method and Television Receiver - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

The present invention relates to a picture in picture display method and a television receiver accordingly.

I. The technical problem that the invention is trying to solve

Digital TV receivers provide picture-in-picture functionality.

All. Summary of Solution of the Invention

Outputting a video stream of a program currently being output and a video stream of any program belonging to the transport stream from a transport stream of a currently tuned channel according to a picture in picture output command; Decoding as first video data through a decoder, decoding a video stream of any one program as second video data through a decoding program, outputting the first video data as a main picture, And outputting the video data to the sub picture.

la. Important uses of the invention

Used for television receivers.

Description

Picture-in-Picture Display Method and Television Receiver

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to television receivers, and more particularly, to a television receiver having a picture in picture (hereinafter referred to as 'PIP') display method and a PIP function.

Conventional analog television receivers have provided a PIP function for simultaneously outputting video of television broadcasts on two or more channels to a water pipe. As the PIP function, the user was able to search for what broadcasting is provided in another channel while continuing to watch the program being watched. In order to implement the PIP function as described above, a conventional analog television receiver should further include a device for receiving and processing television broadcast such as a tuner.

As digital television receivers have been developed, such PIP functions have been required in digital television receivers. Further, providing hardware to provide the PIP function causes a cost increase of the digital television receiver. Therefore, it has also been desired to minimize hardware devices that are further equipped as the PIP function is implemented in a digital television receiver.

As described above, as digital television receivers are developed, there is a demand for a PIP function in a digital television receiver, and in implementing the PIP function, there is a demand for minimizing hardware devices further provided.

Accordingly, an object of the present invention is to provide a PIP display method and a television receiver according to the present invention, which provide a PIP function in a digital television receiver and minimize a hardware device for the PIP function.

1 is a block diagram of a television receiver according to an embodiment of the present invention;

2 is a process flow diagram of the microprocessor of FIG. 1;

3 and 4 are views showing an example of the display of the water pipe according to an embodiment of the present invention,

5 is a block diagram of a television receiver according to another embodiment of the present invention.

According to an aspect of the present invention, a video stream of a program currently being output from a transport stream of a currently tuned channel and a video stream of any program belonging to the transport stream are output according to a picture in picture output command. Decoding the currently output video stream as first video data through a video decoder, decoding the video stream of any one program as second video data through a decoding program, and the first video data. Outputting the main screen and outputting the second video data as a sub-screen.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the annexed drawings, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent to those skilled in the art that the present invention may be practiced without these specific details. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

Digital multichannel television broadcasts, such as US High Definition Television (HDTV), typically transmit multiple programs that are variable over one channel. Here, each program is associated with a digital channel so that a plurality of variable programs transmitted through the channel can be easily distinguished from a user's point of view. Thus, one channel has a plurality of digital channels that can be varied.

The television receiver according to the preferred embodiment of the present invention provides a PIP function of outputting programs of a plurality of digital channels transmitted through one channel to a main screen and a sub-screen according to a user's selection. In addition, the present invention outputs a plurality of digital channels belonging to one channel as a plurality of sub-pictures, so that a user can easily search for a plurality of digital channels belonging to the channel.

Referring to FIG. 1, which shows a block diagram of a television receiver according to an exemplary embodiment of the present invention as described above, the tuner 102 selects a channel selected by a user from a broadcast reception signal through the antenna 100. Tuning is performed under the control of (126). Accordingly, the tuner 102 outputs the channel tuned IF signal to the IF module 104. The IF module 104 converts the IF signal into a baseband signal and inputs it to the channel decoder 106. The channel decoder 106 performs channel decoding on the baseband signal to reproduce a transport stream including video and audio streams for a plurality of digital channels.

The transport stream decoder 108 separates an audio stream and a video stream of any digital channel from the transport stream under the control of the microprocessor 126 and provides them to the audio decoder 110 and the video decoder 116, respectively. And separates a video stream of one digital channel and provides it to the microprocessor 126 through a high speed interface port. The transport stream decoder 108 may use C.CUBE's CL 9110.

The audio decoder 110 decodes the audio stream into audio data and provides the audio stream to the audio processing and output unit 112. The audio processing and output unit 112 processes the audio data as a voice signal and outputs the audio data through the speaker 114.

The video decoder 116 decodes the video stream into video data and provides it to a format converter 118. The format converter 118 provides the video data from the video decoder 116 to an OSG (On Screen Graphic) mixer 120 as it is under the control of the microprocessor 126, or the video decoder 116. Format the video data from the microprocessor 126 to a sub-screen having a predetermined size and outputting the video data provided by the microprocessor 126 at a position predetermined by the microprocessor 126. To the OSG mixer 120. The output of the format converter 118 is provided to the OSG mixer 120, mixed with the OSG provided by the microprocessor 126, processed in the video processing and output unit 122, and then output through the water pipe 124. .

The microprocessor 126 may store a program stored in the memory unit 128 in response to a command input from a keypad 132 or a remote controller 134 through a user interface 130. Perform according to. In this case, the command applied from the remote controller 134 is received by the IR receiver 136 as an IR signal and applied to the user interface 130.

The memory unit 128 may include a read only memory (ROM) for storing programs of various microprocessors 126 including a Motion Picture Expert Group (MPEG) decoding program, and a read only memory (ROM) of the microprocessor 126. Random Access Memory (RAM) for temporarily storing data according to program execution, and EEPROM (Electrically Erasable and Programmable ROM) for storing various reference data for program execution of the microprocessor 126.

A preferred embodiment of the present invention will be described in detail with reference to FIG. 2, which shows a processing flow diagram of the microprocessor 126 of FIG. In operation 138, the microprocessor 126 searches whether the user commands the PIP output through the keypad 132 or the remote controller 134. At this time, if the user inputs the PIP output command, the microprocessor 126 proceeds to step 140, otherwise proceeds to step 154.

In step 140, the microprocessor 126 outputs the video stream of one digital channel of the currently tuned channel along with the output of the video stream and the audio stream of the digital channel being output. Control the decoder 108. Here, the one digital channel may be predetermined as the digital channel currently being output. The audio stream is output to the speaker 114 through the audio decoder 110 and the audio processing and output unit 112. The video stream of the currently output digital channel is decoded through the video decoder 116 and then input to the format converter 118. The microprocessor 126 then drives an amplifier decoding program to decode the video stream from the high speed interface port into video data and provide it to the format converter 118. The microprocessor 126 controls the format converter 118 to convert the video data from the video decoder 116 to the main picture and to output the video data from the microprocessor 126 to the sub picture. The output of the format converter 118 is output to the water pipe 124 through the OSG mixer 120 and the video processing and output unit 122. In this case, the sub-screen S1 may be located at the lower right end of the main screen M as shown in FIG. The size and position of the sub-screen S1 may vary depending on the control of the format converter 118 by the microprocessor 126.

While outputting the PIP as described above, the microprocessor 126 proceeds to step 142 to search whether the user commands the channel switching of the sub screen through the keypad 132 or the remote controller 134. Here, the user may command channel switching within the range of the digital channel belonging to the currently tuned channel. The microprocessor 126 proceeds to step 144 when the user commands channel switching of the sub-screen, and otherwise proceeds to step 146. In step 144, the microprocessor 126 controls the transport stream decoder 108 to output the video stream of the program of the digital channel selected by the user from the digital channel of the currently tuned channel to the high speed interface port. The microprocessor 126 decodes the video stream from the high speed interface port of the transport stream decoder 108 to the format converter 118 so that the video of the program of the user's selected digital channel is displayed as a sub picture. To be printed.

While outputting the PIP as described above, the microprocessor 126 proceeds to step 146 to search whether the user commands the size or position of the sub-screen through the keypad 132 or the remote controller 134. Here, the user may instruct to switch to the size or position of various sub-screens predetermined or directly designate the size or position. The microprocessor 126 controls the format converter 118 to output the sub-screen at the size or position selected by the user when the user instructs the size or position conversion of the sub-screen (150). Proceed to step. In step 150, the microprocessor 126 searches whether the user commands the PIP output termination through the keypad 132 or the remote controller 134. The microprocessor 126 proceeds to step 152 to delete the sub-screen when the user commands the end of the PIP output. Otherwise, the microprocessor 126 proceeds to step 142.

In step 154, the microprocessor 126 searches whether the user commands the channel search through the keypad 132 or the remote controller 134. At this time, if the user commands the channel search, the process proceeds to step 156, otherwise the process proceeds to step 160 to perform the corresponding operation. In step 156, the microprocessor 126 outputs a still screen for all digital channels of the currently tuned channel as a sub picture. More specifically, the microprocessor 126 controls the transport stream decoder 108 to output a video stream for one picture of one digital channel of the currently tuned channel through the high speed interface port. The microprocessor 126 decodes the video stream output to the high speed interface port of the transport stream decoder 108 and provides video data for the screen to the format converter 118. The microprocessor 126 controls the format converter 118 to output the video data to the sub picture and to output the video data from the video decoder 116 to the main picture. Here, the microprocessor 126 continuously provides the video data of one screen to the format converter 118 so that the sub-screen is output as a still screen. When the still screen for one digital channel is output as the sub-picture as described above, the microprocessor 126 outputs the still screens for the remaining digital channels in the above-described manner. Referring to FIG. 4, which shows an example of the output of the water pipe 124 when performing channel search in the above-described manner, video of three digital channels belonging to the channel is displayed on the right side of the main screen M as a still screen. Sub-screens S2, S3, and S4 are located.

When the still screens of the digital channels for the corresponding channel are output as the sub screens as described above, the microprocessor 126 proceeds to step 158 to search whether the user commands the end of the channel search. At this time, when the user commands the end of the channel search, the microprocessor 126 deletes the output sub-screens in step 152.

One embodiment of the present invention described above uses a transport stream decoder that further outputs a video stream through a high speed interface port in the transport stream, and uses the software decoding program to output the additionally output video stream. To decode it. In this way, the PIP function is provided so that no additional hardware is provided. Thus, the television receiver can provide a PIP function while lowering the unit cost of the product.

Unlike in the above-described embodiment of the present invention, the software decoding program is used to decode the video stream output to the high speed interface port of the transport stream decoder. In another embodiment of the present invention, the load of the microprocessor 124 is applied. A separate hardware decoder for decoding the video stream is provided for saving.

Referring to FIG. 5, which shows a block diagram according to another exemplary embodiment of the present invention, the tuner 202 controls the channel selected by the user in the broadcast reception signal through the antenna 200 of the microprocessor 228. Tuning in accordance with. Accordingly, the tuner 202 outputs the channel tuned IF signal to the IF module 204. The IF module 204 converts the IF signal into a baseband signal and inputs it to the channel decoder 206. The channel decoder 206 reproduces the transport stream by channel decoding the baseband signal. The transport stream decoder 208 separates an audio stream and a video stream of a program from the transport stream under the control of the microprocessor 226, and thus the audio decoder 210 and the main video decoder 216, respectively. And a video stream of either program is separated and provided to a sub video decoder 218 through a high speed interface port.

The audio decoder 210 decodes the audio stream into audio data and provides the audio stream to the audio processing and output unit 212. The audio processing and output unit 212 processes the audio data as a voice signal and outputs the audio data through the speaker 214.

The main video decoder 216 decodes the video stream into video data and provides it to a format converter 218. The sub video decoder 218 decodes the video stream input through the high speed interface port of the transport stream decoder 208 into video data and provides the decoded video stream to the format converter 220. The format converter 220 provides the video data from the main video decoder 216 to the OSG mixer 222 as it is or under the control of the microprocessor 228, or the video data from the main video decoder 116. As the main picture, the video data from the sub video decoder 118 is converted to a format to be output to the sub picture and provided to the OSG mixer 222. The OSG mixer 222 mixes the output of the format converter 220 with the OSG provided by the microprocessor 228. The output of the OSG mixer 222 is output through the water pipe 226 after being processed in the video processing and output unit 224.

The microprocessor 228 performs an operation according to a command input from the keypad 234 or the remote controller 236 through the user interface 232 according to a program stored in the memory unit 230. At this time, the command applied from the remote controller 236 is received by the IR receiver 238 as an IR signal and applied to the user interface 232. The microprocessor 228 receives additional data from the transport stream decoder 208, which includes electronic program guide information. The microprocessor 228 receives the electronic program guide information and stores the electronic program guide information in the memory unit 230.

The memory unit 230 may include a ROM for storing a program of the microprocessor 228, a RAM for temporarily storing data according to the execution of the program of the microprocessor 126, an EEPROM for storing various reference data, and the like. It is provided.

Referring to the operation of the television receiver according to another preferred embodiment of the present invention as described above, the microprocessor 228 in the currently tuned channel when the user commands the PIP output via the keypad 234 or the remote controller 236 The transport stream decoder 108 is controlled to output a video stream and an audio stream of a digital channel currently being output, and to output a video stream of one digital channel of the channel to a high speed interface port. Here, the one digital channel may be a digital channel currently being output or a predetermined channel. The audio stream of the currently output digital channel is output to the speaker 214 through the audio decoder 210 and the audio processing and output unit 212. The video stream of the currently output digital channel is decoded through the main video decoder 216 and then input to the format converter 220.

The microprocessor 228 inputs the video stream of the high speed interface port to the sub video decoder 218, and the sub video decoder 218 decodes the video stream into video data and provides it to the format converter 220. Do it. The format converter 220 formats the video data from the main video decoder 216 as a main picture and the video data from the sub video decoder 218 as a sub picture under the control of the microprocessor 228. Convert. The output of the format converter 220 is output to the water pipe 226 through the OSG mixer 222 and the video processing and output unit 224.

As such, another preferred embodiment of the present invention further includes only a video decoder to provide a PIP function, thereby minimizing a hardware device further provided to provide a PIP function.

As described above, the present invention implements the PIP function in a digital television receiver, and in this implementation, there is an advantage that the cost of the product can be lowered by greatly reducing the hardware device.

Claims (4)

In a picture-in-picture display method consisting of a main screen and a sub-screen, Outputting a video stream of a program currently being output from a transport stream of a currently tuned channel and a video stream of any program belonging to the transport stream according to a picture in picture output command; Decoding the currently outputting video stream as first video data through a video decoder; Decoding the video stream of any one program as second video data via a decoding program; And outputting the first video data to a main screen, and outputting the second video data to a sub-screen. The method of claim 1, wherein Outputting a video stream of a program currently being output from a transport stream of a currently tuned channel and a video stream of one screen of all programs belonging to the transport stream according to a user's channel search command; Decoding the video stream of the currently output program as first video data through a video decoder; Decoding the video streams for the one screen as second video data through a decoding program; And outputting the first video data as a main picture, and outputting sub-pictures that are still screens of the decoded second video data. In a television receiver having a picture-in-picture function consisting of a main screen and a sub-screen, A television broadcast signal processor for restoring a transport stream including audio and video transport streams of a plurality of programs from the television broadcast signal; A transport stream decoder for outputting an audio stream, a video stream, and a video stream of a second program for the first program in the transport stream; An audio processor for decoding and processing the audio stream of the first program and outputting the audio stream to a speaker; A video decoder for decoding the video stream of the first program as video data; A format converter for converting the video data of the first program to a main picture and for converting the video data of the second program to a sub picture; A video output unit which processes the output of the format converter and outputs the output to the receiving tube; The video stream of the second program is decoded as video data through a decoding program and provided to the format converter according to a picture in picture output command of a user, and the format converter outputs the video data of the first program to the main screen, And a control unit for controlling the second video data to be output on the sub-picture. In a television receiver having a picture-in-picture function consisting of a main screen and a sub-screen, A television broadcast signal processor for recovering a transport stream including audio and video streams of a plurality of programs from the television broadcast signal; A transport stream decoder for outputting an audio stream, a video stream, and a video stream of a second program for the first program in the transport stream; An audio processor for decoding and processing the audio stream of the first program and outputting the audio stream to a speaker; A first video decoder for decoding the video stream of the first program as video data; A second video decoder for decoding the video stream of the second program as video data; A format converter for converting the video data of the first program to a main picture and for converting the video data of the second program to a sub picture; A video output unit which processes the output of the format converter and outputs the output to the receiving tube; And a control unit for controlling format conversion according to a picture-in-picture output command of the user.