KR100651598B1 - Mobile phone had a video displaying system based on the wipi technology - Google Patents

Abstract

A mobile communication terminal having a WIPI-based video playing system is provided to enable a user to control a decoding process of a decoder when video frame data is played, thereby lowering the memory block copy incidence of the video frame data and accordingly improving the speed of video playing. A video player(100) provides a UI(User Interface) for input of work step information, which a decoder(300) will perform, and transmits the work step information, inputted from a user through the UI, to the decoder(300). The decoder(300) receives and stores the work step information transmitted from the video player(100). According to a video frame data decoding request from the video player(100), the decoder(300) processes corresponding video frame data up to a work step corresponding to the stored work step information and transmits the processed video frame data to the video player(100).

Description

Mobile phone had a video displaying system based on the WIPI technology

1 is a schematic diagram of a conventional video playback system;

2 is a schematic diagram of a Wi-Fi based video playback system according to the present invention;

3 is a flowchart illustrating a decoding process of a Wi-Fi-based video playback system according to the present invention.

<Explanation of symbols for main parts of the drawings>

10, 100: video player 20, 200: Wiffy platform

30, 300: decoder

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication terminal equipped with a Wi-Fi-based video playback system, and more particularly, to a decoding processing technique of video frame data.

Different carriers adopt different wireless application protocol methods (WAP, ME, etc.), and the development environment for each provider's content provider is different, and in the 2nd generation mobile communication base that provided only low level transmission characteristics As the 2.5G and 3G infrastructures of the packet system that can provide high-speed packet transmission are being developed, the multimedia service is being developed in the existing text-oriented wireless internet. It was desperately needed, and the result was the Wireless Internet For Interoperability (WIPI).

A video playback system employing this WIPI technology is shown in FIG.

1 is a schematic diagram of a conventional video reproducing system. As shown in the drawing, a video player 10 for reproducing video frame data and a video player 10 are driven based on WIPI. WIPI Platform 20, and a decoder 30 for decoding the video frame data (Decoder 30).

In order to play the video, the video player 10 delivers the video frame data to be decoded through the WiPi platform 20 to the decoder 30, and the decoder decodes the video frame data and returns to the video player through the WiPi platform 20. Decoding process is passed to (10).

In this process, however, memory block copies of video frame data frequently occur, which causes a decrease in processing speed. In some cases, decoded video frame data is spread late on the screen. As a result, audio and video sync did not match. This phenomenon is exacerbated when the LCD of the terminal becomes large.

That is, referring to FIG. 1, the video player 10 reads video frame data from a memory (not shown) and requests decoding to the decoder 30 (S110) and decoded video from the decoder 30. Receiving and displaying the frame data on the screen (S120), when the user selects a full screen playback (S130), the video player 10 requests the decoder 30 to change the screen size, and the decoder 30 Receiving the decoded video frame data in full screen size on the full screen (S140), and when the user selects a wide screen playback, the video player 10 requests the screen to be rotated to the decoder 30. In step S150 and receiving the video frame data decoded in the wide screen size from the decoder 30 and displaying them on the wide screen, each memory block copy of the video frame data (Memory Block C) is performed. opy) and such a memory block copy occurs every video frame, thus causing the above-mentioned problem.

Accordingly, the present invention provides a technique for improving video playback speed by allowing a user to control the decoding process of a decoder when playing video frame data, thereby reducing the frequency of occurrence of a memory block copy of the video frame data. I did research.

The present invention has been invented under the above-described aspect, and allows a user to control the decoding process of a decoder when playing video frame data, thereby reducing the frequency of occurrence of memory block copies of video frame data. It is an object of the present invention to provide a mobile communication terminal equipped with a playback system.

According to an aspect of the present invention for achieving the above object, a mobile communication terminal equipped with a Wi-Fi-based video playback system according to the present invention, the video player has a user interface (UI) for inputting work step information to be performed by the decoder And transmits the work step information input from the user to the decoder, the decoder receives and stores the work step information transmitted from the video player, and transmits the video frame data according to a request for decoding the video frame data from the video player. The work steps corresponding to the stored work step information may be processed and transmitted to the video player.

Accordingly, the present invention can improve the video playback speed by reducing the frequency of occurrence of a memory block copy of the video frame data in the video frame data decoding process.

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.

2 is a schematic diagram of a Wi-Fi based video playback system according to the present invention.

As shown in the figure, the Wi-Fi-based video playback system according to the present invention exists as a type of software mounted in an ear canal communication terminal, and includes a video player (100) and a Wi-Fi platform (200). And a decoder 300.

The video player 100 is an application for reproducing video frame data, and provides a user interface (UI) for inputting work step information to be performed by the decoder 300, and a job input from the user through the video player. Step information is transmitted to the decoder 300 through the Wi-Fi platform 200.

For example, if the menu for inputting the work step information is provided as one of the menus of the video player 100, and a menu for inputting the work step information is selected by a user's menu operation, the user interface may be selected. UI) is displayed on the screen, and the work step information may be input by selecting one of the steps displayed on the user interface by the user.

In this case, the operation step includes a first step of decoding video frame data, a second step of adjusting the size of the video frame data decoded by the first step according to a full screen size, and the second step. It is preferable to implement so that the third step of adjusting the video frame data adjusted by the step to the wide screen size.

The Wi-Fi platform 200 is a virtual machine (VM) of a wireless Internet standard that drives the video player 100 based on Wi-Fi (WIPI).

The decoder 300 is a software module for decoding video frame data. The decoder 300 receives and stores work step information transmitted from the video player 100, and requests decoding of video frame data from the video player 100. According to the processing, the video frame data is processed up to a work step corresponding to the stored work step information and transmitted to the video player 100.

At this time, the decoder 300 stores the received work step information in a first variable, and upon receiving a video frame data decoding request from the video player 100, initializes a second variable to a first step value, The second variable value may be increased until the first variable and the second variable are the same, and the operation steps corresponding to the second variable value may be sequentially processed.

For example, if the work step information received from the video player 100 is a third step, the decoder 300 stores the third step value in a first variable and requests decoding of video frame data from the video player 100. If present, the second variable is initialized to the first step value, and the second variable is set from the first step value until the first variable is equal to the second variable, that is, until the second variable is the third step value. Decoding the video frame data corresponding to the first step while sequentially increasing from the second step value to the third step value, the video decoded by the first step corresponding to the second step value Adjusting the size of the frame data to the full screen size; and adjusting the video frame data adjusted by the second step corresponding to the third step to the wide screen size. The video frame data is reproduced through the video player 100 by sequentially processing the adjustment operation and transmitting the processed video frame data to the video player 100 through the Wi-Fi platform 200.

Accordingly, the Wi-Fi-based video playback system according to the present invention enables the user to control the decoding process of the decoder when playing the video frame data, thereby reducing the frequency of occurrence of a memory block copy of the video frame data, thereby reducing the video playback speed. It will be possible to improve.

The decoding process of the Wi-Fi based video playback system according to the present invention having the above-described configuration will be described in detail with reference to FIG. 3.

3 is a flowchart illustrating a decoding process of the Wi-Fi-based video playback system according to the present invention.

First, in step S210, the video player 100 provides a user interface (UI) for inputting work step information to be performed by the decoder 300, and through this, the work step information input from the user through the WiPi platform 200. Transmit to decoder 300.

Then, in step S220, the decoder 300 receives the work step information transmitted from the video player 100 and stores it in the first variable.

If video playback is selected by the user, in step S230 the video player 100 reads the video frame data from the memory (not shown) and requests decoding to the decoder 300.

Then, the decoder 300 receives the decoder request from the video player 100, and initializes the second variable to the first step value in step S240.

Next, in step S250, the decoder 300 sequentially processes a work step corresponding to the second variable value while increasing the second variable value until the first variable and the second variable are the same.

If the second variable is larger than the first variable, the decoder 300 transmits the decoded video frame data processed by the step S250 to the video player 100 through the WiPy platform 200 in step S260. The video frame thus transmitted is played through the video player 100.

Accordingly, as described above, the mobile communication terminal equipped with the Wi-Fi-based video playback system according to the present invention allows the user to control the decoding process of the decoder when playing the video frame data, thereby copying a memory block copy of the video frame data. Since the frequency of occurrence can be lowered and the video playback speed can be improved, the above object of the present invention can be achieved.

As described above, the mobile communication terminal equipped with the Wi-Fi-based video playback system according to the present invention allows a user to control the decoding process of the decoder when playing the video frame data, thereby copying a memory block copy of the video frame data. The frequency of occurrence can be lowered, which has a useful effect of improving video playback speed.

While the invention has been described with reference to the preferred embodiments, which are referred to by the accompanying drawings, it is apparent that various modifications are possible without departing from the scope of the invention within the scope covered by the following claims from this description. .

Claims (3)

A video player for playing video frame data, a WIPI platform for driving the video player based on WIPI, and a decoder for decoding video frame data. In the mobile communication terminal equipped with Wi-Fi based video playback system, The video player: Providing a user interface (UI) for inputting work step information to be performed by the decoder, and thereby transmitting work step information input from a user to the decoder; The decoder is: Receives and stores the work step information transmitted from the video player, and processes the video frame data up to the work step corresponding to the stored work step information to the video player according to the video frame data decoding request from the video player. A mobile communication terminal equipped with a Wi-Fi-based video playback system, characterized in that for transmitting. The method of claim 1, The above work steps are: A first step of decoding the video frame data; A second step of adjusting the size of the video frame data decoded by the first step according to a full screen size; A third step of adjusting the video frame data adjusted by the second step to fit a wide screen size; A mobile communication terminal equipped with a Wi-Fi-based video playback system, characterized in that it comprises a. The method according to claim 1 or 2, The decoder is: The received work step information is stored in a first variable, and when a video frame data decoding request is received from the video player, the second variable is initialized to a first step value, until the first variable is equal to the second variable. A mobile communication terminal equipped with a Wi-Fi-based video playback system, characterized in that the processing steps corresponding to the second variable value are sequentially processed while increasing the second variable value.

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