KR100223643B1 - Apparatus and method for setting up error correction the number of retry automatically - Google Patents

Abstract

end. TECHNICAL FIELD This invention relates to error correction of an optical disc reproducing apparatus.

I. SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus and method for automatically setting an error correction repetition frequency according to a demodulation success rate of data reproduced through an optical pickup in an optical disc reproducing apparatus.

All. SUMMARY OF THE INVENTION A device for automatically setting an error correction repetition frequency of an optical disc reproducing apparatus, comprising: a demodulator for inputting a modulated data stream reproduced through an optical pickup and demodulating and outputting a symbol unit consisting of predetermined bits; And a synchronization detection unit for generating and outputting an error correction synchronization detection signal for detecting an error correction time point from the modulated data stream so as to read data in a single error correction block, and a counting value of the error correction synchronization detection signal. A counter that initializes and outputs data indicating a demodulation error to the error correction memory when the group of data selected from the data stream is not present in the conversion table, and counts the number of demodulation errors and accumulates them in a single error correction block unit; Based on the last counter value of the counter for the error correction block And a control unit for comparing with a reference value and setting an error correction repetition frequency according to the comparison result.

la. Important use of the invention: It can be used for the system decoder of the optical disc player.

Description

Error correction repetition frequency automatic setting device and method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to error correction in an optical disc reproducing apparatus, and more particularly, to an apparatus and method for automatically setting an error correction repetition frequency using demodulated errors counted during reproduction data demodulation.

Optical discs such as Compact Discs (CDs) and Digital Video Discs (DVDs) are difficult to accurately reproduce digital signals due to careless handling during disc manufacturing or use. In general, the difference between the original signal and the reproduced signal is called a drop out. The drop out includes ① mastering and manufacturing of the optical disc, ② adsorbing foreign substances or scratches on the surface of the optical disc, and ③ servo Or a phenomenon in which the synchronization signal is scattered. Therefore, the optical disc reproducing apparatus cannot expect normal reproduction of recorded data without correcting the dropout caused by the above factors.

Hereinafter, an error correction process performed in the optical disc reproducing apparatus will be described in detail with reference to the configuration of a DVD-ROM drive decoder as an example of the optical disc reproducing apparatus.

1 shows a block diagram of a general DVD-ROM drive decoder, and FIG. 2 shows an example of a general error correction block structure. Referring first to FIG. 1, the EFM data stream reproduced through the optical pickup is input to the 32-bit shift register 10 and converted into parallel data. The 16/8 demodulator 12 selects the lower (or upper) 16 bits of the 32 bits of the output of the 32-bit shift register 10, converts them into 8-bit data forming one symbol, and outputs them. This is due to 8/16 modulation (Eight to Sixteen Modulation) when recording data on the optical disk. The synchronization detector 14 inputs the output of the 32-bit shift register 10 to find frame synchronization as a standard clock for controlling the rotation of the optical disk, sector synchronization for sector division, and error correction time, and finds the corresponding error correction. Signals are generated and output according to the detection of various synchronization patterns such as an error correction synchronizer for reading data in the block. The data ID detection unit 16 detects a data ID from the data output from the 16/8 demodulator 12 and performs error correction of the detected ID data. The error-corrected ID data is transmitted to the microcomputer 34 with the ID error flag and used for the search of the optical disk. The main data error correcting unit 18 corrects the error in the horizontal and vertical directions with respect to the predetermined error correction block under the control of the microcomputer 34 when 16 sectors of data is written to the memory 28. The structure of the error correction block will be described with reference to FIG. 2. First, the error correction block has a codeword length of 182 bytes in the horizontal direction and the parity has a length of 10B (Byte). The longitudinal direction has a length of 208B and the parity has a length of 16B. Therefore, the unit for error correction is 37856B (182B * 208B), which corresponds to 16 sectors. For error correction, the error correction block as shown in FIG. 2 may be formed by collecting ID data and main data output from the 16/8 demodulator 12 and storing them in predetermined block units. Therefore, the memory 28 shown in FIG. 1 represents a DRAM used for error correction and a buffer. The memory control unit 26 connected to the memory 28 is controlled by the microcomputer 34 and generates memory control related signals such as a low address signal, a column address signal, and the like necessary for error correction or buffering of the playback data. 28) access control. The deinterleave unit 20 may be implemented by means of storing an interleaving rule, an address counter, an adder, and the like. By controlling the write / read address of the memory 28, the original array is also reduced by reducing the data interleaved in units of frames. Save it. The descrambler 22 inputs main data stored in the memory 28 after error correction is completed, descrambles it, and restores the original data. The error detector 24 detects an error included in data output from the descrambler 22. The interface unit 30 is responsible for interfacing the DVD-ROM drive decoder with a host computer. The microcomputer 34 controls the overall operation of the DVD-ROM drive through the microcomputer I / F (Interface) 32.

In the DVD-ROM drive decoder having the above-described configuration, error correction is controlled by the microcomputer 34. That is, error correction is performed by the control of the microcomputer 34 only when all 16 sectors of data are recorded in the memory 28, and whether or not the error correction is repeated is also performed by the control of the microcomputer 34. FIG. When there are many errors in the demodulated data, it is common to perform error correction in the horizontal direction once more.

mode Frequency of error correction One Landscape, Portrait 2 Landscape, Portrait, Landscape

Table 1 illustrates the number of error correction performed by the DVD-ROM drive decoder under the control of the microcomputer 34. In the table 1, when the microcomputer 34 sets the mode 1, the main data error correction unit 18 performs the error correction once in the horizontal and vertical directions with respect to the error correction block, and the microcomputer 34 performs the mode 2 If set, the main data error correction unit 18 performs error correction in the horizontal and vertical directions, and again in the horizontal direction with respect to the error correction block. However, in the general optical disc reproducing apparatus, since the error correction repetition number is set and performed uniformly by the microcomputer 34, unnecessary error correction is often performed. That is, even if all errors in the error correction block are recovered as a result of one error correction in the horizontal and vertical directions, if the microcomputer is currently setting mode 2, the error correction in the horizontal direction is performed once more. There is a problem that power for accessing 28) is unnecessarily consumed.

Accordingly, an object of the present invention is to provide an apparatus and method for automatically setting an error correction repetition frequency according to a demodulation success rate of data reproduced through an optical pickup in an optical disc reproducing apparatus.

It is still another object of the present invention to optimize an error correction repetition frequency for a single error correction block in an optical disc reproducing apparatus having an error correction memory according to whether or not an error is detected in demodulated data, thereby preventing unnecessary power consumption. An apparatus and method for automatically setting an error correction repetition frequency are provided.

The present invention for achieving the above object in the error correction repetition frequency automatic setting apparatus of the optical disk playback apparatus,

A demodulator which inputs a modulated data stream reproduced through an optical pickup, demodulates the data by symbol unit consisting of predetermined bits;

A synchronization detection unit for generating and outputting an error correction synchronization detection signal for detecting an error correction time point from the modulated data stream so as to read data in a single error correction block;

The counting value is initialized by the error correction synchronization detection signal, and when a group of data selected from the data stream is not present in the conversion table, a data indicating the demodulation error is output to the error correction memory and the number of demodulation errors is counted. A counter that accumulates and outputs in correction block units,

And a control unit for comparing the final counter value of the counter with respect to a single error correction block with a reference value and setting an error correction repetition frequency according to the comparison result.

The present invention also provides a demodulator for inputting a modulated data stream reproduced through an optical pickup and demodulating and outputting the demodulated data in symbol units consisting of predetermined bits, and counting values are initialized by an error correction synchronization detection signal. A counter for counting and outputting the number of demodulation errors generated in units of a single error correction block, frame synchronization as a standard clock for controlling the rotation of the optical disk from the modulated data stream, sector synchronization for sector division, and error correction timing A method for automatically setting an error correction repetition frequency of an optical disc reproducing apparatus decoder, comprising at least a synchronization detecting unit for generating and outputting an error correction synchronization detection signal for detecting and reading data in a single error correction block.

While the data is being reproduced, a final counter value of the number of demodulation errors for the single error correction block is input and compared with a reference value. According to the comparison result, one error correction mode is selected from among a plurality of error correction setting modes. It is characterized by performing error correction.

1 is a block diagram of a general DVD-ROM drive decoder.

2 is an exemplary error correction block structure.

3 is a block diagram of a DVD-ROM drive decoder equipped with an apparatus for automatically setting an error correction repetition frequency according to an embodiment of the present invention.

FIG. 4 is a flow chart illustrating output data according to the demodulation operation of the 16/8 demodulator and the counter 12 in FIG.

5 is an error correction iteration automatic setting control flow chart according to an embodiment of the present invention.

Hereinafter, a method for automatically setting an error correction repetition frequency according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. It should be noted that the same components in the following description and drawings are to have the same reference numerals as much as possible even if shown on different drawings. In addition, many specific details such as the number of error correction repetitions, the number of data, and the specific processing flow appear, which are provided to help a more comprehensive understanding of the present invention, and the present invention may be practiced without these specific details. It will be obvious to those skilled in the art. In the following description of embodiments of the present invention, detailed descriptions of related known functions or configurations will be omitted if it is determined that the detailed descriptions may unnecessarily obscure the subject matter of the present invention.

FIG. 3 is a block diagram of a DVD-ROM drive decoder equipped with an apparatus for automatically setting an error repetition frequency according to an embodiment of the present invention, in which a counter for counting a demodulation error is added to a 16/8 demodulator. Except that, the configuration is the same as that of the general DVD-ROM drive decoder shown in FIG. Referring to FIG. 2, an EFM data stream reproduced through an optical pickup is input to an EFM demodulator and demodulated in units of symbols consisting of predetermined bits. The EFM demodulator is composed of a 32-bit shift register 10, a 16/8 demodulator and a counter 12. That is, the EFM data stream is input to the 32-bit shift register 10, converted into parallel data, and output. The 16/8 demodulator and the counter 12 output the lower 32 bits of the output 32-bit of the 32-bit shift register 10. Alternatively, select the higher 16 bits to demodulate the EFM modulated data. The demodulation process and the demodulation error counting process in the 16/8 demodulator and counter 12 will be described in more detail. First, the peripheral conversion table and the sub-conversion table are used to perform the demodulation process. If there is no value in the tables corresponding to the 16 bit data selected from < RTI ID = 0.0 > 1, < / RTI > Therefore, when the demodulation process does not have a demodulated value in the conversion table, the counter is counted using the counter. This has the effect of detecting a demodulation error of the selected 16-bit data during the demodulation process. The reference time for counting the number of demodulation errors is from the start of the error correction block, and once a single error correction block has been written to the memory 28, the counting value up to now is initialized and the demodulation error is reset for the next error correction block. The count is counted. The counting value of the demodulation error number is transmitted to the microcomputer 34 through the microcomputer I / F 32. On the other hand, the synchronization detecting unit 14 inputs the output of the 32-bit shift register 10 to detect frame synchronization as a standard clock for controlling the rotation of the optical disk, sector synchronization for division of sectors, and error correction timing to detect a single error. Error correction synchronization detection signals are generated and output so that data in the correction block can be read. In addition, an operation of setting a window for acknowledging only synchronization detection within a predetermined range or forcibly generating a detection signal when a predetermined synchronization detection is not performed is performed. The data ID detection unit 16 detects a data ID from the data output from the 16/8 demodulator 12 and performs error correction of the detected ID data. The error-corrected ID data is transmitted to the microcomputer 34 with the ID error flag and used for the search of the optical disk. On the other hand, the microcomputer 34 can know which part of the optical disk is currently being reproduced through the data ID detection unit 16, so that the position to be played back can be found. The main data error correction unit 18 performs error correction in the horizontal and vertical directions with respect to the predetermined error correction block under the control of the microcomputer 34 when 16 sectors of data are written to the memory 28. In the embodiment of the present invention, the horizontal and vertical lengths are 182B, 172B, and 10B, and 208B, 192B, and 16B, respectively. In this case, 182B and 208B represent lengths of codewords in the horizontal and vertical directions, respectively, and 172B and 192B represent main data lengths in the horizontal and vertical directions, respectively. 10B and 16B show the length of parity. Therefore, the unit for error correction is 37856B (182B * 208B), which corresponds to 16 sectors. On the other hand, the memory 28 is divided into two blocks, and the 16/8 demodulated data is recorded in one block of the memory 28, and error correction is performed in the remaining blocks. The memory control unit 26 connected to the memory 28 is controlled by the microcomputer 34 and generates memory control related signals such as a low address signal, a column address signal, and the like necessary for error correction or buffering of the playback data. 28) access control. The deinterleave unit 20 may be implemented by means of storing an interleaving rule, an address counter, an adder, and the like. By controlling the write / read address of the memory 28, the original array is also reduced by reducing the data interleaved in units of frames. Save it. The descrambler 22 inputs the error corrected main data, descrambles it, restores the original data, and outputs the original data. The error detector 24 detects an error included in data output from the descrambler 22. The interface unit 30 is responsible for interfacing the DVD-ROM drive decoder with a host computer. The microcomputer 34 includes a RAM for temporarily storing the ROM stored in the control program according to an exemplary embodiment of the present invention and data generated during a control operation, and performs overall operation of the DVD-ROM drive according to the control program stored in the ROM. To control. For example, the microcomputer 34 sets the error correction repetition number by comparing the counting value of the number of demodulation errors output from the 16/8 demodulator and the counter 12 with a preset reference value, and accordingly the main data error correction unit 18. Control the operation of In the above-described configuration, components other than the microcomputer I / F 32, the microcomputer 34, and the interface unit 30 can be one-chip as a DVD-ROM decoder.

FIG. 4 is a view illustrating a process of generating output data according to a demodulation operation of the 16/8 demodulator and the counter 12 in FIG. 3, and FIG. 5 is a flowchart illustrating an error setting repetition frequency automatic setting control according to an embodiment of the present invention. will be.

Hereinafter, a method for automatically setting an error correction repetition frequency according to an embodiment of the present invention will be described in detail with reference to FIGS. 3 to 5.

First, the signal picked up from the DVD-ROM disc surface is input to the 32-bit shift register 10 as an EFM data stream and converted into parallel data. The 16/8 demodulator and counter 12 select the lower (or higher) 16 bits of the 32 bits of the 32-bit shift register 10 to start demodulating the EFM-modulated data. In the first step of the demodulation process, that is, step 40 of FIG. 4, the counter value is initialized by the synchronization detection signal input from the synchronization detection unit 14. Thereafter, the 16/8 demodulator and the counter 12 demodulate the 16-bit data into 8 bits when the selected 16-bit data exists in the demodulation table. Otherwise, FF hexadecimal data is output in step 46. The counter initialized in step 48 is incremented by one. Therefore, in the 16/8 demodulator and the counter 12, steps 42 to 48 are repeatedly performed until the demodulation operation for one error correction block is completed, so that the number of demodulation errors for one error correction block is counted. After the demodulation operation for one error correction block is terminated in step 50, the final counter value of the counter is output to the microcomputer 34 in step 52. The counter is reinitialized by the synchronous detection signal and repeatedly counts the number of demodulation errors for one error correction block. According to the error correction theory, the number of data that can be corrected by error correction in the horizontal and vertical directions for the DVD format is 150 (10 * 15) bytes. Therefore, if the value of the counter is 150 or less, one error correction may be performed in the horizontal direction and the vertical direction. If the number exceeds 150, the error correction in the horizontal, vertical and horizontal directions may be performed. Therefore, when the microcomputer 34 compares the value of the last counter output from the 16/8 demodulator and the counter 12 with 150 and sets the error correction repetition number according to the comparison result, unnecessary power consumption can be reduced. .

Hereinafter, a process of setting an error correction repetition frequency by comparing the value of the last counter output from the 16/8 demodulator and the counter 12 with 150 will be described with reference to FIG. 5. In the following description, the numerical value 150 will be defined as a reference value.

First, when a data reproducing command is received from the host computer in step 60, the microcomputer 34 proceeds to step 62 to perform a series of servo control for reproducing predetermined data from the target track. In step 64, predetermined data is reproduced while tracking servo control of the optical pickup. If the final counter value for one error correction block is input from the 16/8 demodulator and the counter 12 in step 66 during data reproduction, the microcomputer 34 proceeds to step 68 and compares the input last counter value with the reference value. do. If the result of the comparison indicates that the final counter value is less than or equal to the reference value, the microcomputer 34 proceeds to step 70 to set the first error correction mode, otherwise proceeds to step 72 to set the second error correction mode. The first error correction mode is a mode that is set to perform one error correction in the horizontal and vertical directions with respect to one error correction block, and the second error correction mode is one in the horizontal, vertical and horizontal directions. This mode is set to perform error correction. As described above, the microcomputer 34 sets the error correction mode according to the number of demodulation errors by comparing the value of the last counter with a reference value, and performs error correction in step 74 according to the set mode. In FIG. 5, only the error correction repetition frequency setting process for one error correction block is illustrated, but the above-described error correction repetition frequency automatic setting routine is repeatedly performed according to the data length to be reproduced.

In the embodiment of the present invention, an apparatus and method for setting an error correction repetition number have been described by illustrating a DVD-ROM decoder, but the present invention can be applied to a CD-based optical disc reproducing apparatus and a DVD-based optical disc reproducing apparatus without any modification. Therefore, the scope of the invention should not be defined by the described embodiments, but should be defined by the equivalent of claims and claims.

As described above, in the present invention, in setting the error correction repetition frequency of the error correction chip used in the optical disc reproducing apparatus, the error correction repetition frequency is automatically set according to the counting result of the number of demodulation errors of the data reproduced from the optical disc. By reducing the number of times of error correction memory access, there is an advantage that the power consumption can be accordingly.

Claims (4)

In the error correction repetition frequency automatic setting device of the optical disc player, A demodulator which inputs a modulated data stream reproduced through an optical pickup, demodulates the data by symbol unit consisting of predetermined bits; A synchronization detection unit for generating and outputting an error correction synchronization detection signal for detecting an error correction time point from the modulated data stream so as to read data in a single error correction block; The counting value is initialized by the error correction synchronization detection signal, and when a group of data selected from the data stream is not present in the conversion table, a data indicating the demodulation error is output to the error correction memory and the number of demodulation errors is counted. A counter that accumulates and outputs in correction block units, And a control unit which compares the last counter value of the counter with respect to a single error correction block with a reference value and sets the error correction repetition frequency according to the comparison result. The apparatus of claim 1, wherein the error correction repetition frequency automatic setting device is manufactured by a one-chip IC excluding the control unit. A demodulation unit for inputting a modulated data stream reproduced through an optical pickup, demodulating the data in a symbol unit consisting of predetermined bits, and a counting value initialized by an error correction synchronization detection signal, and a demodulation error occurring in a demodulation process of the modulated data. A counter for counting and outputting the number of units in a single error correction block unit, frame synchronization as a standard clock for controlling the rotation of the optical disk from the modulated data stream, sector synchronization for sector division, and error correction timing by detecting a single error. A method of automatically setting an error correction repetition frequency of an optical disc reproducing apparatus decoder, comprising at least a synchronous detection unit for generating and outputting an error correction synchronous detection signal for reading data in a correction block. While the data is being reproduced, a final counter value of the number of demodulation errors for the single error correction block is input and compared with a reference value. According to the comparison result, one error correction mode is selected from among a plurality of error correction setting modes. An error correction repetition frequency automatic setting method characterized in that error correction is performed. The method of claim 3, wherein the error correction setting mode is divided into error correction frequency differences in a horizontal direction and a vertical direction with respect to the single error correction block.

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