KR100224868B1 - Method for detecting error data correction range - Google Patents

Abstract

The present invention relates to a data error correction method, and more particularly, to a data error correction range determination method for reducing normal data deletion by minimizing a correction range of error data generated during decoding of received data.

The present invention provides a forward decoding error detection process for detecting an error of data while executing forward decoding, a forward error position detection process for detecting a forward error block position of an error-detected first predetermined unit during the forward decoding, and the forward decoding error detection. If an error is detected in the process, a reverse decoding error detection process of detecting an error in the data while stopping forward decoding and decoding the data being decoded in the reverse direction; And an error correction range determining step of setting a data error correction range of data between the forward error block and both error blocks including the backward error block.

According to the present invention, by minimizing an error correction range by backward decoding, loss of normal data can be reduced, and high quality reproduction can be performed in the case of video data processing.

Description

Data error correction range judgment method

The present invention relates to a data error correction method, and more particularly, to a method of determining a data error correction range for minimizing a correction range of error data generated in a decoding process of received data to reduce the deletion of normal data.

Generally, data received by portable telephone communication in a metropolitan city center or satellite communication in bad weather inevitably includes an error, and a method of reducing such an error greatly affects the data processing speed of the communication.

The error data correction method according to the prior art has two methods that are typically used.

One of them is a method of repeatedly retransmitting the data of the part where an error is detected until the error is not detected between the decoder and the encoder. This method drastically reduces the processing power of the communication channel, which is closely related to the number of retransmissions.

Another method is to discard the data of a GOB (Group Of Block) including a macro block (MB: Macro Block) in which an error is detected, for example, of a video data processing processor, This is a method of processing data from the same GOB instead of discarded data.

As shown in FIG. 3, if an error is detected while decoding the sixth macro block MB constituting GOB 2 of the Nth frame, the decoder does not decode until the next GOB sync signal is found. If the synchronization signal of GOB 3 is found, all data of the current GOB 2 of the Nth frame is discarded, and the data of GOB 2 of the (N-1) th frame is copied to the GOB 2 area of the Nth frame. However, if the next GOB sync signal is GOB 5, all data in the area of the Nth frame GOB 2, 3, 4 is discarded, and the data of GOB 2, 3, 4 of the (N-1) th frame is discarded. Copy to the GOB 2, 3, and 4 areas.

This second conventional method has the disadvantage of discarding a large amount of data in which no error occurs.

The error correction methods according to the related art as described above have a problem in that a processing capacity of a communication channel is drastically reduced or a large amount of normal data is discarded.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a data error correction range determination method for minimizing an amount of data that does not occur when discarding data in order to solve the above problems.

1 is a flowchart of a data error correction range determination method according to the present invention.

2 (a)-(c) illustrate various forms of error correction ranges determined by the present invention.

Figure 3 shows an error correction execution method according to the prior art.

In order to achieve the above technical problem, the method of determining a data error correction range according to the present invention includes a method of determining a data block of a second predetermined unit that constitutes one block by a data block of a first predetermined unit and a data block of a first predetermined unit. A method of determining a data error correction range during decoding, comprising: a forward decoding error detecting step of detecting an error of data of a first predetermined data block while performing forward decoding, and a first data including error data detected by the forward decoding error detecting step A forward error position detection process for detecting a forward error block position that is a data block position of a predetermined unit, and if an error is detected in the forward decoding error detection process, the last first constituting a data block of a second predetermined unit that has been decoded and is being decoded. Decode backward from one block of data A reverse decoding error detection process for detecting an error of data while executing ding, and a backward error position detection for detecting a reverse error block position which is a data block position of a first predetermined unit including the error data detected in the reverse decoding error detection process And an error correction range determination step of setting a data error correction range between the error block including the forward error block and the backward error block.

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

1 is a flowchart illustrating a method of setting a data error correction range according to an embodiment of the present invention, in which a forward decoding process 110 decodes data forwardly and a first error determination process 120 determining whether an error has occurred in the data during the forward decoding process. ), A first macro block position detection process 130 for detecting a position of a macro block including error detected data during forward decoding, a decoding data shift process for moving a macro block for decoding data to the last macro block of the current GOB 140, a backward decoding process 150 for backward decoding, a second error determination process 160 for determining whether an error has occurred in reverse decoding data, a reverse decoding error, and a position of a macro block including detected data is detected. The second macro block position detection process 170, which has an error between the first macro block and the second macro block An error correction range determination process 180 for determining data as an error correction range and an error correction process 190 for correcting data in the error correction range are provided.

In the detailed description of the present invention, the above processes will be described using multimedia video data processing as an example. Since the decoding of the received communication is well known, a detailed description of the decoding is omitted, and the decoding may be performed in any subunit of one data block.

In the video data for multimedia, a data set of the minimum unit of data processing such as a video signal is called a block, and one macro block is composed of a certain number of blocks, and one GOB is a constant number of macro blocks. (Group Of Block) and constitutes one frame with a certain number of GOBs.

The forward decoding process 110 is a process of forward decoding the input compressed video data. That is, the process of decoding the data of the macro block constituting the GOB in order of the position of the macro block.

The first error determination process 120 is a process of determining whether an error occurs while performing forward decoding. That is, it is a process of determining whether a syntax error occurs in data during decoding. If it is determined that an error has occurred, the execution of forward decoding is stopped and the following steps are performed.

The first macroblock position detection process 130 is a process of detecting a position of a first macroblock which is a macroblock including data in which an error occurs when an error occurs as a result of the determination of the first error determination process 120.

The decoding data shift process 140 is a process of shifting the data to be decoded into the macro block of the last part of the current GOB that was being decoded when an error is detected in the first error detection process 120.

The backward decoding process 150 is a process of decoding from the macro block of the last part of the GOB to the macro block of the previous position sequentially. That is, in the case of H.263, backward decoding refers to an entropy coder table and a syntax table in the reverse order of macro blocks starting from the bottom level of the sintex.

The second error determination process 160 is a process of determining whether an error occurs while performing reverse decoding. That is, it is a process of determining whether a syntax error occurs in data during reverse decoding. If it is determined that an error has occurred, execution of reverse decoding is stopped.

The second macro block position detection process 170 is a process of detecting the position of the second macro block, which is a macro block including data in which an error occurs during the execution of the second error determination process 160.

The error correction range determination process 180 may include a first macroblock in which a forward decoding error fe is detected and a second macroblock in which a backward decoding error be is detected, as shown in FIGS. 2A to 2C. It is a process of determining the block data between the error correction range. Of course, the first macroblock and the second macroblock are also included.

An example of an error correction range corresponding to a forward decoding error and an error detected in reverse decoding may be represented by (a), (b) and (c) of FIG. 2. In the case of (a) and (b), the block data between the forward decoding error of the predetermined block data including the forward decoding error and the backward decoding error and the macroblock including the backward decoding error are determined as an error correction range, In the case of (c), a single macro block is determined as an error correction range when the positions of the macro blocks in which the forward decoding error and the reverse decoding error occur are the same.

The error correction process 190 discards data between the first macroblock and the second macroblock in which the error correction range of the frame currently being decoded is determined, and at the position, between the first macroblock and the second macroblock of the frame immediately preceding the position. The process of copying block data into a macro.

Through the above process, the present invention can minimize the amount of data discarded due to an error.

Although the detailed description of the present invention has been described using video data processing as an example, it is obvious to those skilled in the art that the present invention is not limited thereto and may be applied to all fields for correcting errors in digital data.

As described above, according to the present invention, by minimizing an error correction range by reverse decoding, loss of normal data can be reduced, and high quality reproduction can be performed in the case of video data processing.

Claims (5)

In the data error correction range determination method of decoding a data block of a second predetermined unit constituting one block by a set of a data block of a first predetermined unit and a data block of the first predetermined unit which is a predetermined data configuration unit, A forward decoding error detecting process of detecting an error of data of the data block of the first predetermined unit while performing forward decoding; A forward error location detection step of detecting a forward error block location that is a data block location of a first predetermined unit including the error data detected in the forward decoding error detection step; When an error is detected in the forward decoding error detection process, the execution of the forward decoding is stopped and the decoding of the data is performed in the reverse direction from the data block of the last first predetermined unit constituting the data block of the second predetermined unit which was being decoded. Backward decoding error detection process; A backward error location detection step of detecting a backward error block location that is a data block location of a first predetermined unit including the error data detected in the backward decoding error detection step; And And an error correction range determining step of setting a data error correction range between the error block including the forward error block and the backward error block. The method of claim 1, wherein the data block of the first predetermined unit is a data error determination block of a minimum unit. A method of determining an error correction range of data arranged in a data block of a second unit including a first unit data block and the first unit data block set arranged from a first position to a last position, the method comprising: (a) performing decoding in a forward direction from the data block of the first first unit; (b) determining whether an error in the forward decoding is detected in the data; (c) detecting a position of a forward error block that is a position of the data block of the first unit including the error detected in step (b); (d) If an error is detected in step (b), the forward decoding is stopped and the decoding of the data is performed in the reverse direction from the data block of the last first predetermined unit constituting the data block of the second predetermined unit that was being decoded. Detecting; (e) determining whether an error occurs in data during the backward decoding; (f) detecting a position of a backward error block that is a position of the first predetermined unit data block including the error detected in step (e); and (g) setting a data error correction range between both error blocks including the forward and backward error blocks. 4. The method of claim 3, wherein the data block of the first predetermined unit is a data error determination block of a minimum unit. 4. The method of claim 3, further comprising performing error correction on the error correction range.

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