KR100620179B1 - Error Correction Method According to Playback Speed of Optical Disc - Google Patents

Abstract

The present invention finds the minimum number of times that the recorded data to be detected is continuously error corrected at each reproduction speed of the optical disk that is inserted and rotated, and determines the optimal number of error corrections for the corresponding speed. An error correction method according to the reproduction speed of an optical disc such that the number of error corrections performed on the recorded data is performed by a predetermined optimal error correction number in consideration of the reproduction speed of the optical disc during reproduction of the optical disc. A first step of error correcting a signal read and reproduced from the optical disk within a predetermined error correction number, on the basis of an inspection execution frequency value arbitrarily set corresponding to the current reproduction speed of the optical disk; A second step of checking whether the error is corrected; A third step of determining an optimal number of error corrections according to the reproduction speed according to the error correction result checking result; And a fourth step of storing the determined optimal number of error corrections in association with the corresponding reproduction speed, which is a very useful invention that eliminates the time required for performing unnecessary error correction or switching the speed.

Description

Error Correction Method According to Playback Speed of Optical Disc

The present invention relates to an error correction method according to the reproduction speed of an optical disc such that the number of times of error correction on the recording data read and reproduced from the optical disc is varied according to the reproduction speed of the optical disc. At each reproduction speed of the optical disk that is inserted and rotated, the minimum number of times that the detected recording data is continuously error corrected is found and determined as the optimal number of error corrections for the corresponding double speed. The present invention relates to an error correction method according to the reproduction speed of an optical disc such that the number of error corrections performed on the recording data is performed by a predetermined optimal error correction number in consideration of the reproduction speed of the optical disc.

1 is a block diagram of a general optical disc reproducing apparatus, comprising: a pickup section 11 for detecting a recording signal from the surface of an inserted optical disc 10; A drive unit 21 for driving motors 12a and 12b for rotating the pickup unit 11 and the inserted optical disc 10, respectively; An R / F unit 20 for filtering the signal detected by the pickup unit 11; The driving of the drive unit 21 is controlled from the output signal of the R / F unit 20 and the rotational speed of the optical disk 10, and the synchronization of the output signal of the R / F unit 20 is detected. Servo unit 22; A data strobe unit 30 for restoring a high frequency signal read by the R / F unit 20 into a digital bit stream using the detected synchronization; An EFM inverse transformer (40) for demodulating the restored 14-bit EFM data into 8-bit data; A CIRC decoder (50) for performing error detection and correction on the demodulated data in error correction block units; And a control unit 60 for controlling the servo unit 22 and setting the number of error corrections of the CIRC decoder 50.

In the optical disc reproducing apparatus configured as described above, first, when the optical disc 10 is inserted and mounted, the control unit 60 controls the pickup unit 11, as shown in FIG. 2 from the data area of the optical disc. The error correction unit blocks recorded as are sequentially read, and the signals read by the pickup unit 11 are filtered by the R / F unit 20 and then digitally filtered by the data strobe unit 30. It is restored to the bitstream and output as EFM converted digital data.

When the data strobe unit 30 detects an error occurrence of data due to a drop out during a digital bitstream restoration process, the data strobe unit 30 generates a specific signal and applies it to the control unit 60. The EFM The inverse transformer 40 inverts the digital symbol data of the 14-bit unit to be converted into 8-bit symbol data corresponding to the corresponding transformation, and outputs the data. The data conversion of the EFM inverse transformer 40 is performed by the EFM shown in FIG. This is done based on the conversion table.

When the control unit 60 receives a specific signal indicating a reproduction error from the data strobe unit 30, the control unit 60 controls the CIRC decoder 50 to control the digital data inputted by the EFM demodulation within a preset number of times. in the C1 decoder for the error correction to the CIRC decoder (50) (C1 ^-1) is in the detecting the error of data from the C1 code (32,28) that are sequentially input from the EFM inverse transformer 40, it originally and recover to a normal output data, C1 code sequence outputted from the C1 decoder (C1 ^-1) are to be entered sequentially temporarily stored in a buffer in the CIRC decoder 50, excluding a certain amount of column C1 code parity After the completion of storage, C2 decoder (C1 ^-2) reads out the code C2 (28,24) stored in the buffer and to recover the original data from the top, during the error correction process described above, the error data array: If the corrective ability is exceeded and it is not restored to the original normal data, the controller 60 causes the error correction process to be repeatedly performed within a predetermined number of times.

However, when the error data is not restored to the original normal data even after performing the error correction process for the predetermined number of times, the controller 60 controls the spindle through the servo unit 22 and the drive unit 21. By regulating the drive voltage applied to the motor 12b, the reproduction speed of the optical disc 10 is adjusted to a low speed, and the read data of the corresponding position is read back from the optical disc 10 which is driven to rotate at a low speed. And the error correction process as described above is performed again.

However, in the error correction method of the optical disc reproducing apparatus configured as described above, when the error data read and reproduced from the optical disc is not restored to the normal data even after performing the error correction process a predetermined number of times, the optical disc is unconditionally. After adjusting the playback speed to low speed, re-read the recorded data at the corresponding position and repeating the error correction process. After repeating error correction, the playback speed of the optical disc is readjusted to the original playback speed. Thereafter, playback of the recorded data is performed or the error correction process is performed a predetermined number of times despite error correction at the corresponding speed, and then the low speed switching and rereading process is performed. There was a problem that the playback time is unnecessarily delayed in the playback of.

Accordingly, the present invention has been created to solve the above problems, and detects and stores the optimal number of error corrections according to each reproduction speed of the optical disc, and then reproduces the optical disc to use the same for subsequent optical disc reproduction. The purpose is to provide an error correction method according to the double speed.

The error correction method according to the reproduction speed of the optical disk according to the present invention for achieving the above object, based on the value of the number of times of test execution arbitrarily set corresponding to the current reproduction speed of the inserted optical disk, a predetermined error correction A first step of error correcting a signal read from and reproduced from the optical disc within a number of times; A second step of checking whether the error is corrected; A third step of determining an optimal number of error corrections according to the reproduction speed according to the error correction result checking result; And a fourth step of storing the determined optimal number of error corrections in association with the corresponding reproduction speed.

In the error correction method according to the reproduction speed of the optical disk according to the present invention made as described above, if the optical disk is rotated and driven at a predetermined speed after the optical disk is inserted and mounted, a predetermined arbitrarily set corresponding to the current reproduction speed of the optical disk. If the error correction signal is read and reproduced from the optical disk within the error correction number, and the error correction is successfully performed within the number of test executions set according to the current reproduction speed, the predetermined value is determined according to the result. The number of error corrections is determined as the optimal number of error corrections according to the current playback speed.

Hereinafter, a preferred embodiment of the error correction method according to the reproduction speed of the optical disk according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 4 shows the configuration of a preferred embodiment of the optical disc reproducing apparatus for implementing the error correction method according to the reproduction speed of the optical disc according to the present invention. The memory 61 is configured to further store the optimal error correction number according to the configuration.

5 and 6 are flow charts showing the flow of a preferred embodiment of the error correction method according to the reproduction speed of the optical disk according to the present invention, and with reference to the configuration of the playback device of FIG. The method for determining the number of error corrections of FIG. 6 will be described in detail.

First, when the optical disk 10 is inserted and initialized (S10), the control unit 60 drives the spindle motor 12b through the servo unit 22 and the drive unit 21, so that the optical disk ( 10), wherein the control unit 60 applies the drive voltage corresponding to the requested double speed to the spindle motor 12b such that the regeneration speed of the optical disc 10 becomes the requested double speed. In the state where the optical disc 10 is rotationally driven at the requested double speed, the controller 60 controls the current playback speed that is being driven, the number of error corrections N arbitrarily set corresponding to the playback speed, and The number of checks (M) is checked (S11). For example, when the current playback speed of the optical disc 10 is 4 times, it is confirmed that the number of error corrections is three times and the number of inspections is two times, based on the table shown in FIG. 7A.

In this state, the control unit 60 checks whether or not an error of the recording data read and reproduced from the optical disc 10 is performed (S12), and the reproduction data is transmitted to the data strobe unit 30 as described above. If it is determined by the error data (S20), the control unit 60 controls the CIRC decoder 50 to correct the error within the range of the number of error correction for the data generated in the bitstream recovery process To perform the process (S21). That is, since the checked number of error corrections (N) is three times, the CIRC decoder 50 performs an error correction process up to three times of the input data, and the control unit 60 performs the CIRC decoder 50. It is checked whether or not the error occurred data is restored to the original normal data (S30).

As a result of the check, when the error-produced data is restored to the original normal data, the controller 60 decreases the arbitrarily set error correction count and inspection count once (N-1, M-1) ( In step S31, the controller determines whether the reduced value is a target value, that is, the number of error corrections is 1 (S40) or the number of checks is 0 (S41). As a result of the check, if the value decreased once by one is not the target value, the controller 60 decreases the one time for the above-described process, that is, the recorded data read out from the current playback position of the optical disc 10. The error correction process as many times as the error correction, the success or failure of the process of checking the error, the error correction number and the number of times of the test according to the success check result is repeatedly performed, so that the control unit 60 the error correction number Is 1 or when the number of checks is 0, the controller 60 determines an optimal number of error corrections at this time, wherein the number of error corrections is finally 1 In this case, 1 is the optimal number of error corrections, but if the number of error corrections is not 1 (for example, 2 times), the number of checks is performed a limited number of times, so that the value of the variable for the number of checks is If 0, the optimum number of error corrections is determined twice (S42). As shown in Fig. 7B, the current reproduction speed is stored in the memory 61 in association with the determined optimal number of error corrections.

However, if it is determined that the error correction has failed in the error correction success check step (S30), the controller 60 increases the number of times of the arbitrarily set error correction once (N + 1) (S50), the increase As long as the set value is not the preset maximum limit value MAX (S60), the CIRC decoder 50 is controlled to restore from the data strobe unit 30 within the increased number of times (N + 1). The error correction is performed again on the input data (S61).

During the error correction, if the error correction succeeds in a range in which the increased error correction value does not exceed the preset maximum limit value (S70), the controller 60 sets the arbitrarily set number of inspection times to 1. It is reduced (M-1) (S71), and then checking whether it is a target value for the increased number of error corrections (S40) and checking whether the reduced number of checks is zero (S41) again. By doing so, as described above, the optimal number of error corrections is determined.

In addition, in the above embodiment, when the number of error correction is increased by one time until the success of error correction is confirmed, when the increased number of error correction becomes a preset maximum limit value MAX, the controller 60 is The pickup section 11 is controlled to reread the data which has been subjected to the previous error correction on the basis of the stored position value on the optical disk 10 (S62), and a restoration error still occurs in the reread and reproduced data. When it is generated (S80) and the restoration error signal is regenerated from the data strobe unit 30, the control unit 60 through the servo unit 22 and the drive unit 21 through the spindle motor 12b By reducing the driving voltage applied to, the mounted optical disk 10 is adjusted to rotate at a low speed (for example, 2 times speed) to be driven in rotation (S90).

As such, when the rotational speed of the optical disc 10 is lowered to a low speed, the control unit 60 is set to correspond to the reproduction speed of the optical disc 10 with low speed adjustment and the adjusted reproduction speed. The number of error corrections N and the number of inspections M are checked (S91), and then the operation is repeatedly performed from the step S21 of performing error correction as described above. The optimal number of error corrections depending on the reproduction speed of the adjusted optical disc 10 is determined.

By the way, in the step of checking whether the read-out data is in error (S80), when the data to be read-out and read-out is confirmed as normal data, the controller 60 displays the current number of error corrections in the current state of the optical disc 10. It is determined by the optimal number of error corrections according to the reproduction speed (4 times speed), and for this reproduction speed (4 times speed), in case of error correction failure, data read-out from the optical disc 10 is immediately re-readed (Re-Read). It is set to perform from the process (S81).

As such, when the optimal number of error corrections or rereads for each reproduction speed of the inserted optical disc 10 are determined and stored in the memory 61, the subsequent optical disc 10 is reproduced. The recovery process of the errored data is performed based on the optimal number of error corrections stored or determined for re-reading the recorded data read and reproduced from the optical disc 10.

The error correction method according to the reproduction speed of the optical disk according to the present invention made as described above detects and stores the optimal number of error corrections according to each reproduction speed of the inserted optical disk, When the error correction is performed, the error correction is performed as many times as the optimal number of error corrections that have been detected and stored, thereby eliminating the time required for performing unnecessary error correction or switching the speed.

Fig. 1 shows the configuration of a general optical disc player,

Fig. 2 shows the form of a recording frame recorded on an optical disc,

3 shows a part of the EFM conversion table;

4 shows a configuration of an optical disc reproducing apparatus for implementing an error correction method according to reproduction speed of an optical disc according to the present invention;

5 and 6 are flowcharts showing the flow of a preferred embodiment of the error correction method according to the reproduction speed of the optical disk according to the present invention;

FIG. 7A shows an example of the number of error corrections and the number of inspections arbitrarily set according to each reproduction speed of the optical disc;

Fig. 7B shows, by way of example, the optimum number of error corrections for each reproduction speed of the optical disc determined in accordance with the present invention.

※ Explanation of code for main part of drawing

10 optical disc 11 pickup portion

12a, 12b: Motor 20: R / F part

21: drive portion 22: servo portion

30: data strobe part 40: EFM inverse converter

50: CIRC decoder 60: control unit

61: memory

Claims (7)

In the method of playing an optical disc, A first step of error correcting a signal read and reproduced from the optical disk within a predetermined error correction number, based on a check number of execution times arbitrarily set corresponding to the current playback speed of the inserted optical disk; A second step of checking whether the error is corrected; A third step of determining an optimal number of error corrections according to the reproduction speed according to the error correction result checking result; And And a fourth step of storing the determined optimal number of error corrections in association with the corresponding reproduction speed. The method of claim 1, The third step is. Reducing the predetermined number of error corrections upon confirming the success of the error corrections; And If the reduced value becomes a predetermined minimum number of error correction times, determining the value as an optimal number of error corrections according to the reproduction speed. . The method of claim 1, The third step, Changing the number of checks performed when the error correction succeeds; And Determining the reduced number of predetermined error corrections as an optimal number of error corrections according to the reproduction speed when the changed number of times of performing the test is a preset limit value. Error correction method. The method of claim 1, The third step, Increasing the predetermined number of error corrections upon checking the failure of the error correction; Performing error correction on the basis of the increased number of times; And And determining an optimum number of error corrections in accordance with the reproduction speed, in accordance with the execution result. The method of claim 1, The third step, Rereading a recording signal on the optical disk upon confirmation of the failure of the error correction; Adjusting a reproduction speed of the optical disc to a low reproduction speed when a reproduction error of the signal to be read back is reproduced; And And re-performing from the error correction process of the first step by resetting a predetermined error correction number of times according to the adjusted low speed. The method of claim 1, The third step, Rereading a recording signal on the optical disk upon confirmation of the failure of the error correction; Determining a predetermined number of error correction times according to a current reproduction speed of the optical disc during normal reproduction of the reread signal; And And resetting the data from the optical disc upon reproducing error of a signal read and reproduced from the optical disc driven at the same speed as the reproduction double speed. . The method of claim 1, And a fifth step of performing the first to fourth steps again for other reproduction speeds of the optical disc.