KR100195256B1 - Data continuity verification method of dvd - Google Patents

Abstract

Disclosure the data continuity verification method of DVD. The method includes a first process of generating a predetermined first signal according to reliability of continuous ID data, and adding 1 to current ID data when the first signal is generated with respect to previous and current ID data. A second process of allocating the predicted value of the ID data, a third process of increasing the predicted value of the next ID data by 1 each time the ID sink is generated when the first signal is not generated, and the predicted value of the previous ID data and the current ID Comparing the data, and if the comparison is not the same, a fourth step of re-detecting from the next ID data after the first signal was last generated.

Description

How to verify data continuity of DVD

The present invention relates to a digital versatile disc (DVD), and more particularly, to a method for verifying data continuity of a DVD.

In general, even if the error correction code sync of the DVD is correctly protected, there is a possibility that an arbitrary track jump phenomenon may occur due to a slip phenomenon during data read from the disc. This track jump causes unwanted data. Therefore, data continuity must be verified to determine whether it is a normal track jump or slip phenomenon. Try to redetect based on the result of this judgment.

An object of the present invention to provide a data continuity verification method of the DVD.

1 is a view for explaining a data continuity verification method of the DVD according to the present invention.

The data continuity verifying method of the DVD according to the present invention for achieving the object of the present invention described above is based on the first process of generating a predetermined first signal according to the reliability of the continuous ID data, and the previous and current ID data. In the second process, when the first signal is generated, 1 is added to current ID data to be assigned as a predicted value of the next ID data, and when the first signal is not generated, a predicted value of the next ID data is generated every time the ID sink is generated. A third step of incrementing by one, and a fourth step of comparing the predicted value of the previous ID data with the current ID data, and redetecting the next ID data from which the first signal was last generated if the comparison result is not the same. .

Hereinafter, a method of verifying data continuity of a DVD according to the present invention will be described in detail with reference to the accompanying drawings.

When pickup picks up data from the disc, it is possible to jump randomly to different tracks due to various factors, so it is necessary to verify the continuity of the data to accurately predict it. At this time, the continuity verification of the data is performed using the last three bytes of ID data indicating the serial number of the sector. First, reliability determination is performed on ID data read from the disc, and an IDOK signal is generated according to the reliability determination result. The condition under which the IDOK signal is generated uses the flag signal generated as a result of the error correction. That is, the flag signal refers to SIDF1 generated regardless of an error correction result when one or more errors are generated as a result of the first syndrome calculation, and SIDF2 generated when error correction is impossible because two or more errors exist. At this time, since SIDF2 includes the conditions of SIDF1, SIDF1 may be regarded as more accurate. The reliability of the ID data is determined using the flag signals SIDF1 and SIDF2 and SYOK and NOSY indicating the accuracy of the ID sync, and an IDOK signal is generated according to the result. In this case, the SYOK signal refers to a signal generated when the detected sync signal matches the counted sync signal, and the NOSY signal refers to a signal generated when there is no sync signal in the window. Looking at the conditions under which the IDOK signal is generated, the result of the AND operation of the SYOK and SIDF2 signal is a low level, or the active high level when the AND operation result of the NOSY and SIDF1 signal is a low level. When the IDOK signal is generated for the previous and current ID data, the microcomputer (not shown) recognizes the reliability of the detected ID data and continues reading the data. At the same time, 1 is added to the current ID data to predict the next ID data. Assign. At this time, the predicted value is a comparison value with the next ID data. However, when the IDOK signal is not generated, the predicted value of the next ID data is incremented by 1 for each ID sync and waits for the next IDOK signal to be generated. The predicted value of the previous ID data is compared with the current ID data. If the result is not the same, an interrupt (IEINT) is generated by a microcomputer (not shown), and the IDOK signal is finally generated, and the next ID data is detected again. Data blocks that do not generate an IDOK signal are not reliable because they do not know where continuity is broken. However, even if the IDOK signal is not generated continuously, if the continuity is not broken, it is not a serious problem of the whole data. Therefore, error correction is sufficient without having to detect the data stored in the buffer again.

As described above, the present invention has the advantage that it is possible to determine whether it is due to track jump or slip when an abnormality occurs by presenting the predicted value of the next ID data whenever it is determined to be correct ID data and comparing them with each other. .

Claims (1)

A first step of generating a predetermined first signal according to whether the successive ID data are reliable; A second process of adding 1 to current ID data and assigning it as a predicted value of the next ID data when the first signal is generated with respect to previous and current ID data; A third step of increasing the predicted value of the next ID data by 1 whenever the first signal is not generated when the first signal is not generated; And And comparing the predicted value of the previous ID data with the current ID data, and if it is not the same as the result of the comparison, verifying the data continuity of the DVD, characterized in that it comprises a fourth step of redetecting the next ID data after the first signal was last generated. Way.