KR100238146B1 - Method for processing error flag in optical disc reproducing apparatus during reproducing disc - Google Patents

Abstract

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

Error correction of an optical disc reproducing apparatus.

B. Technical problem to be solved

The present invention relates to an error flag processing method for preventing the occurrence of impulsive noise due to miscorrection during error correction in an optical disc reproducing apparatus.

C. Summary of the Solution

Among the C2 error-corrected data, if the error flag is marked as an error during C1 error correction, check whether the error occurs by calculating the C1 syndrome polynomial again before the final output, and if the error occurs, the C2 error-corrected data The C2 error flag corresponding to the data displayed as an error when correcting the C1 error is replaced with an error flag indicating that there is an error.

D. Significant Uses of the Invention

It is used to play a disc in an optical disc player.

Description

Error flag handling method when playing on optical disc player

The present invention relates to an optical disc reproducing apparatus, and more particularly, to an error flag processing method during reproduction of an optical disc reproducing apparatus.

In general, when an optical disc is reproduced, an error occurs due to various reasons (noise, inter-signal interference, fluctuation of playback mechanism, media error, etc.) and the original digital signal cannot be transmitted without correction. Therefore, errors can be detected and corrected through various methods.

1 shows a partial configuration of a conventional optical disc reproducing apparatus, wherein the memory 102 is a dynamic RAM. The microcomputer 110 is a device controller which controls the overall operation of the optical disc reproducing apparatus as a whole, and inputs error detection information to control error correction. The demodulator 100 reads from a disk and demodulates the information, which is shaped as a pulse waveform, that is, the data stream ESM in symbol units consisting of predetermined bits and outputs the demodulated data. Typically, optical discs perform eight to sixteen modulations when writing data to the disc. The error correction unit 108 corrects a predetermined block of data read from the disk. The memory controller 104 forms an error correction block by allocating an appropriate address to the memory 102 under the control of the microcomputer 110 and providing the corresponding demodulated data. The error correction block consists of data for 16 sectors. The memory 102 also buffers data between the two directions of error correction and stores corrected data. The interpolation & digital filter unit 106 restores error corrected data to original analog data.

FIG. 2 is a flowchart illustrating an error correction and error flag processing process in a conventional optical disc reproducing apparatus. The operation of each step will be described in detail based on the configuration of FIG. 1.

First, the microcomputer 110 descrambles the data read from the disk in operation 200, and then reads the descrambled data in predetermined block units for C1 error correction. Next, the microcomputer 110 proceeds to step 202 to check whether the data read in the predetermined block unit is error correctable. In this case, if an error that exceeds the error correction range occurs in the data of the predetermined block unit, the microcomputer 110 proceeds to step 204 and sets the C1 error flag to logic "high" in the data where the error occurs in the block data. And bypasses without performing C1 error correction.

On the contrary, when the data in the predetermined block unit is error correctable in step 202, the microcomputer 110 applies the block data to the error correction unit 108 to perform C1 error correction and then the data in step 206. Replace with C1 error-corrected data and set the C1 error flag to a logic "low" to indicate no error. Next, the microcomputer 110 proceeds to step 208 to deinterleave the C1 error corrected data and read the deinterleaved data in predetermined block units for C2 error correction. Next, the microcomputer 110 checks whether the data of the predetermined block unit is capable of correcting C2 errors. In this case, if the error occurs as much as the block data is out of the C2 error correction range, the microcomputer 110 proceeds to step 212 and sets the C2 error flag to logical "high" in the data where the error occurs in the block data. Indicates that the data is generated and bypasses it without performing error correction.

On the contrary, if the data of the predetermined block unit is capable of error correction in step 210, the microcomputer 110 performs C2 error correction on the block data through the error correction 108 and then in step 214. Replace the data with C2 error-corrected data and set the C2 error flag to logic "low" to indicate no error. The microcomputer 110 proceeds to step 216 and outputs the C1 and C2 error-corrected final data and error flag to the interpolation & digital filter unit 106.

However, the above-described conventional error correction and error flag processing process may be performed by determining that data whose error flag is set to logic "high" as C1 error correction is error correctable due to miscorrection when C2 error correction. When the error flag set to logic "high" at the time of C1 error correction went through the C2 error correction process, the C2 error flag was incorrectly set as logic "low", that is, there was no error.

FIG. 3 illustrates an example of an output signal and a C2 error flag that are finally output through the error correction and error flag processing of FIG. 2, and the section A of FIG. As shown in FIG. 2, the error flag is displayed as a logical "low", that is, error-free data.

As shown in FIG. 3 and FIG. 3, when the incorrect data is output as it is, impulsive noise occurs in the audio output during reproduction.

As described above, in the process of error correction and error flag processing, it is determined that data cannot be corrected when correcting C1 error, and the data in which an error flag is displayed as data having an error is incorrectly determined to be error correctable due to miscorrection in C2 error correction process. There was a case in which the final output is generated, and if the data incorrectly corrected as described above are generated as impulsive noise during reproduction.

Accordingly, an object of the present invention is to provide an error flag processing method capable of preventing data from being incorrectly corrected during C2 error correction and being generated as noise during audio output.

1 is a view showing a partial configuration of a conventional optical disc player;

2 is a flowchart of processing an error flag when correcting an error in a conventional optical disc player;

3 is a view showing an example of an audio output waveform that is output by processing an error flag during reproduction in a conventional optical disc player;

4 is a flowchart of processing an error flag when correcting an error in an optical disc reproducing apparatus according to an exemplary embodiment of the present invention.

The present invention for achieving the above object is to check whether the error occurs by calculating the C1 syndrome polynomial once again before the final output for the data indicated that the error flag at the time of C1 error correction error, out of the C2 error correction data When is generated, the C2 error flag corresponding to the data displayed as the error during the C1 error correction among the C2 error corrected data is replaced with an error flag indicating that there is an error.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Many specific details are set forth in the following description and in the accompanying drawings to provide a more general understanding of the 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.

4 illustrates a process of processing error correction and an error flag according to an embodiment of the present invention. Now, embodiments of the present invention will be described in detail with reference to FIGS. 1 and 4.

First, as shown in FIG. 2, the microcomputer 110 descrambles the data read from the disk in operation 400, and then reads the descrambled data in a predetermined block unit for C1 error correction. Next, the microcomputer 110 proceeds to step 402 to check whether the data read in the predetermined block unit is error correctable. In this case, if an error that exceeds the error correction range occurs in the data of the predetermined block unit, the microcomputer 110 proceeds to step 404 to set the C1 error flag to logic "high" in the data in which the error occurs in the block data. Setting and bypass without performing C1 error correction.

On the contrary, if the data in the predetermined block unit is error correctable in step 402, the microcomputer 110 applies the block data to the error correction unit 108 to perform C1 error correction and then the data in step 406. Is replaced with C1 error-corrected data and the C1 error flag corresponding to the C1 error-corrected data is set to a logic "low" to indicate that there is no error. Next, the microcomputer 110 proceeds to step 408 to deinterleave the C1 error corrected data again, and then reads the deinterleaved data in a predetermined block unit for C2 error correction. In operation 410, the microcomputer 110 checks whether the data of the predetermined block unit is capable of correcting C2 errors. In this case, if the error occurs as much as the block data is out of the C2 error correction range, the microcomputer 110 proceeds to step 412 and sets the C2 error flag corresponding to the data in which the error occurs in the block data to logic "high". Set to indicate that an error has occurred and bypass it without performing error correction.

On the contrary, when the data in the predetermined block unit is capable of error correction in step 410, the microcomputer 110 performs C2 error correction on the block data through the error correction unit 108 and then in step 414. Replace the data with C2 error-corrected data and set the C2 error flag corresponding to the C2 error-corrected data to a logic "low" to indicate that there is no error. For example, the C1 error flag is temporarily stored. Next, the microcomputer 110 proceeds to step 416 to calculate the C1 syndrome polynomial again with respect to the C2 error corrected data, and proceeds to step 418 to check whether an error occurs. The C1 syndrome polynomial refers to a polynomial used to determine the presence or absence of an error of data in the predetermined block unit during C1 error correction. If an error occurs as a result of the calculation of the C1 syndrome polynomial in step 418, the microcomputer 110 proceeds to step 420 and the error in the C1 error correction process among the data corrected for C2 error in step 414. For the data that was marked as having occurred, the C2 error flag corresponding to the data is set to a logic "high" again. In other words, it indicates that an error has occurred. The microcomputer 110 proceeds to step 422 and outputs the final error corrected data to the interpolation & digital filter unit 106 along with the C2 error flag. As a result, the error-corrected final data can be reproduced and output as an audio signal.

Therefore, it is possible to prevent the data in which an error occurs during C1 error correction from being incorrectly determined to be data without error due to a miscorrection in C2 error correction.

As described above, the present invention can prevent the occurrence of impulsive noise in the audio output during reproduction due to miscorrection during C2 error correction by checking the C2 error corrected data once again with the C1 syndrome polynomial. There is this.

Claims (1)

In a method for processing an error flag during playback in an optical disc player, Performing C1 error correction by descrambling the data input from the disk and reading the data in a predetermined block unit; Setting and outputting an error flag indicating that an error has occurred in the data that cannot be corrected when performing the C1 error correction; Deinterleaving the C1 error corrected data and reading the data again in a predetermined block unit to perform C2 error correction, and setting and outputting the C2 error corrected data to a C2 error flag indicating that there is no error; If the C2 error corrected data includes data in which an error occurred when correcting the C1 error, checking whether an error occurs by calculating a C1 syndrome polynomial again; If an error occurs as a result of the calculation of the C1 syndrome polynomial, the C2 error flag of the C2 error corrected data is set to C2 error flag indicating that the error data is again generated. An error flag processing method during playback in an optical disc player.

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