KR0144836B1 - Decoding method and apparatus - Google Patents

Abstract

The present invention relates to a method and an apparatus for receiving and decoding digital video and audio signals. Since the head data having various information about the decoder and the video data, which are video information signals, are sequentially transmitted, the decoder can restore the data. In order to solve the problem that the decoding time becomes relatively long and the data processing becomes complicated, the data recovery operation must be stopped in the decoding unit during the period in which the data input is discontinuous and the data is not transmitted. The separated video data and the head data are temporarily stored by using the memory and then outputted, and then converted into a continuous form. The head data separator is used to separate the head data according to each mode. Outputting head data It relates to a decoding method and apparatus for the continuous treatment of continuous data. Therefore, the present invention has the effect of reducing the decoding time, simplifying the hardware and facilitating control.

Description

Decoding method and apparatus for continuous processing of discontinuous data

FIG. 1 is an arrangement diagram showing a transmission format of data, FIG. 2 is a block diagram of a decoding apparatus for continuous processing of discontinuous data according to the present invention, and FIG. 3 is an input data of FIG. 2 apparatus and data output from each processing unit. Array diagram showing the format.

* Explanation of symbols for main parts of the drawings

10: Video separator 20, 30: Memory

30: Head data separator

The present invention relates to a method and apparatus for receiving and decoding digital video and audio signals, and more particularly, to a decoding method for continuous processing of discontinuous data for discontinuously converting data into continuous data using a memory. To the device.

In general, video signals and audio signals are digitally transmitted or digitally processed in order to pursue high quality and high sound quality and to make signal processing easier and more efficient. In this case, since the amount of data is large, it is difficult to process in real time when encoding only by A / D conversion, and it takes a lot of time for transmission or recording. In order to reduce the transmission cost, various coding schemes have been proposed. HD TVs, which are recently attracting attention, are coded and transmitted through processes such as DCT (Discrete Cosine Transform), Quantizer, Variable Length Coding (VLC), and the like. It mainly uses the signal processing method to restore the original signal through At this time, the transmitted image data has a transmission format as shown in FIG. The transmission data of FIG. 1 includes overhead data, head data, and video data, and since the head data having various information about the decoder and the video data, which are input image signal information, are sequentially transmitted, the data is decoded. The department receives data input in a discontinuous form when restoring the data. Due to such discontinuous data input, the decoding unit must stop the data restoration operation during the period in which the video data is not transmitted, thereby causing a relatively long decoding time and complicated data processing.

Accordingly, an object of the present invention is to provide a decoding method for continuously processing discontinuous data.

Another object of the present invention is to provide an apparatus for implementing a decoding method for the continuous processing of the discontinuous data described above.

As described above, an object of the present invention is to provide a variable length-decoded data in a form of a bitstream in which head data and video data are mixed, and a decoding method for restoring data by receiving state information thereof. A first step of separating and outputting the mixed video data and the head data in the data; a second step of receiving the video data and the head data separated by the first step, storing the rearranged data into a continuous data form, and And a third step of reading the head data stored in the second step into the head data for each mode by a predetermined control signal, and the head data for each mode in the third step and the video data stored in the second step are synchronized with each other. A decoding method for continuous processing of discontinuous data comprising a fourth step of outputting to the next decoding means. Is achieved.

Another object of the present invention is to provide a variable length decoded data in which a head stream and a video data are mixed, and a decoding apparatus for receiving data and restoring the state information thereof, wherein the variable length decoding is performed based on the state information. A video data separator which separates the video data and the head data mixed in the data, and the head data applied from the video data separator are stored according to the first write clock signal, and the head is stored as the head data separator according to the first read clock signal. A first memory for applying data and a video data applied from the video data separator are stored according to the second write clock signal, and the video data stored in the next decoding unit is continuously applied according to the second read clock signal. The second memory and the head data continuously rearranged from the first memory are received. With a predetermined control signal separated by the data head in accordance with each mode, and is achieved by the decoding apparatus for the continuous processing of discrete data to a head data splitter for outputting the head data separated into the next stage of decoding.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a decoding apparatus for continuous processing of discontinuous data according to the present invention. First, a state signal ST and input data from a variable length decoder (hereinafter referred to as VLD) (not shown) are shown. The IET is received by the video data separator 10 and separated into the head data HDT and the video data VDT so that the head data HDT is the first memory 20 and the video data VDT is the second. Configured to store each into memory 30. The memories 20 and 30 receive the respective read / write clock signals CLK _R1 , CLK _W1 , CLK _R2 and CLK _W2 , and the first memory 20 stores data stored at an input terminal of the head data separator 40. The second memory 30 is connected to output the video data stored in the input terminal of the decoding unit (not shown) of the next stage. In addition, the head data separator 40 separates the continuous head data according to each mode by a control signal CTL applied from a predetermined controller (not shown) and outputs the data to the next decoding unit (not shown). It is configured to.

The operation of the present invention configured as described above will be described in more detail with reference to FIG.

FIG. 3 is an arrangement diagram showing the input data of the apparatus of FIG. 2 and the format of the data output from each processing unit. First, transmission data having the same form as that of FIG. The video data separator 10 is converted into an input data IDT having the same data format and mixed with the video data b and the head data a, and a status signal ST having information on the arrangement order of the input data. ), The video data separator 10 converts the input data IDT to the head data HDT (b) and the video data as shown in FIGS. 3 (b) and 3 (c) by the state signal ST. Output separately by (VDT) (a). In this case, the video data (VDT) has image information, and the head data (HDT) divides the inter mode, the intra mode, the frame mode, and the field mode. Has information The first memory 20 stores the head data HDT according to the first write clock signal CLK _W1 applied from a predetermined controller (not shown), and the second memory 30 stores the second write clock signal. Store video data (VDT) according to (CLK _W2 ). The heads and video data continuously rearranged in the first and second memories may be generated in units of one frame such that the head data separator 40 and the decoder of the next stage do not overflow the respective memories 20 and 30. Read by the first and second read clock signals CLK _R1 and CLK _R2 . At this time, each read / write clock signal CLK _R1 , CLK _R2 , CLK _W1 , CLK _W2 is asynchronously applied. As described above, in order to read video data continuously for one frame, two frame memories must be used. However, when two frame memories are used, the hardware becomes complicated. Therefore, a single first-in first-out memory (FIFO) can be used to implement the simpler method. After the head data and the video data are converted into the continuous form through the memories 20 and 30 as described above, the head data separator 40 reads the continuous head data according to the first read clock signal CLK _R1 . The head data is separated in accordance with each mode by the control signal CTL applied from a predetermined control unit (not shown). At this time, the control signal CLK of the head data separator 40 matches the read point of the second memory 30 and the latch point of the head data separator 40 so that the third (d) and the third ( As shown in e), continuous video data (V1, V2, V3, ...) and head data (H1, H2, H3, ...) are simultaneously output.

Therefore, the decoding unit (not shown) of the next stage always receives data arranged continuously.

As described above, the decoding method for continuous processing of discontinuous data according to the present invention reduces the decoding time by separating video data and head data input discontinuously during video signal decoding using a memory and converting the data into continuous data. This has the effect of simplifying the hardware and facilitating control.

Claims (4)

In the decoding method for receiving data of variable length decoded data in the form of a bit stream in which head data and video data are mixed, and state information thereof, the video data mixed with the variable length decoded data based on the state information. And a first step of separating and outputting head data; a second step of receiving and storing the video data and the head data separated by the first step, respectively, and rearranging them into a continuous data form; A third step of reading the head data and separating the head data into respective head data according to a predetermined control signal; And a fourth step in which the head data for each mode of the third step and the video data stored in the second step are synchronized with each other and output to the next decoding means. . A decoding apparatus for receiving data of variable length decoded data in a form of a bit stream in which head data and video data are mixed, and state information thereof, and comprising: video data mixed with variable length decoded data based on the state information. And video data separating means for separating the head data, respectively; storing the head data applied from the video data separating means according to a first write clock signal, and storing the stored head data into the head data separating means according to the first read clock signal. A first memory configured to store the video data applied from the video data separating means according to a second write clock signal, and apply the stored video data to a next decoding means according to a second read clock signal. 2 memory; And discontinuous data including head data separation means for receiving continuously rearranged head data from the first memory to separate the head data according to each mode by a predetermined control signal, and output the separated head data to the decoding means. Decoding apparatus for continuous processing of the. 3. The decoding apparatus of claim 2, wherein the first and second read clock signals and the first and second write clock signals are generated asynchronously. The method of claim 2, wherein the control signal of the head data separating means separates the head data for each mode and outputs the head data for each mode in accordance with the second read clock signal of the second memory. Decoding device for continuous processing.