KR20040067103A - Method for encoding and decoding error correction block in high density optical disc - Google Patents

Abstract

PURPOSE: A method for encoding and decoding an ECC(Error Correction Code) block of a high-density optical disk is provided to declare an eraser if a burst error which is continuous in vertical or horizontal direction exists in an ECC block, thereby minimizing an ECC error and effectively suppressing an error caused by a random error. CONSTITUTION: A system generates user data blocks having a predetermined recording size. The system generates a PO(Parity Outer) for a vertical data string among the user data blocks, and records at least more than one SCP(Syndrome Check Parity) for separately declaring an eraser on a horizontal data string at certain intervals within the user data blocks. When recording more than one SCP, the system generates synchronous bytes with the SCP to record at least more than one synchronous byte within the user data blocks.

Description

Method for encoding and decoding error correction block in high density optical disc

The present invention relates to an error correction block encoding and decoding method of a high density optical disc which is optimal for a next generation high density optical disc having a higher recording density than a DVD.

An error correction code (ECC) suitable for a general DVD format is a Read Solomon Code (RS Code). The error correction in the DVD is RS (182, 172, 11). Interleaved with the configured inner code and the outer code consisting of RS (192, 208, 17), up to five errors can be corrected in the inner, and up to eight errors can be corrected in the outer. .

On the other hand, as shown in Figure 1, one error correction block (ECC Block), each of 16 outer parity (PO: Parity Outer per vertical) to the scrambled '172 X 192' bytes of User Data (User Data) ) Is added, and a code word of '182 X 208' bytes to which 10 inner parity inners (PI) are added per horizontal direction is included.

In addition, as shown in FIG. 2, the codewords of the error correction block have a configuration scheme in which 16 outer parities are interleaved to 12 inner codewords, and a total of 208 inner codewords are all 16 sectors. 1 sector consists of 13 inner codewords, so that 1 error correction block is 16 sectors, 1 sector is 13 codewords, and 1 inner codeword is 182 bytes. .

However, when a burst error continuous in the lateral direction or the longitudinal direction exists in the error correction block of the DVD format configured as described above, the error correction capability is extremely degraded, so that normal user data cannot be restored. In particular, in the case of a next generation high density optical disc having a higher recording density than a DVD, a fatal error correction error due to a burst error occurs.

Accordingly, the present invention was created to solve the above problems, and has a burst error continuous in the transverse direction or the longitudinal direction in an error correction block (ECC Block) of a next-generation high-density optical disc having a higher recording density than a DVD. If Burst Error exists, Eraser can be declared to minimize error correction error due to burst error and to effectively suppress occurrence of error correction error due to random error. It is an object of the present invention to provide an error correction block encoding and decoding method for a high density optical disc.

1 and 2 show a configuration of an error correction block of a general DVD (DVD),

3 conceptually illustrates an encoder to which an error correction block encoding method of a high density optical disc according to the present invention is applied;

Fig. 4 shows the construction of the first embodiment of the error correction block of the high density optical disc according to the present invention.

5 conceptually illustrates a decoder to which an error correction block decoding method of a high density optical disc according to the present invention is applied;

6 and 7 illustrate a first specific embodiment of an error correction block of a high density optical disc that is encoded and decoded according to the present invention.

8 to 10 show a second embodiment of an error correction block of a high density optical disc encoded and decoded according to the present invention,

11 to 13 show a third embodiment of an error correction block of a high density optical disc which is encoded and decoded according to the present invention.

※ Explanation of code for main part of drawing

10: data block generation unit 11: PO generation unit

12: SCP generator 20: SCP calculator

21: PO calculation unit 22: Data block generation unit

100: encoder 200: decoder

The error correction block encoding method of the high density optical disc according to the present invention for achieving the above object comprises the steps of: generating a user data block of a predetermined recording size; and the outer parity of the data column in the longitudinal direction of the user data block; And generating at least one syndrome check parity in the user data block so as to generate an erasure declaration for the data column in the lateral direction at predetermined intervals. Features,

In addition, an error correction block decoding method of a high density optical disc according to the present invention includes: detecting a syndrome check value for a plurality of syndrome check parities recorded in a data column in a horizontal direction among the error correction blocks; Declaring an eraser when an error occurrence position having a non-zero value in the detected syndrome check value is continuously generated in syndrome check parity recorded in a corresponding interval in the data column; And performing an error correction operation on a longitudinal data string using the outer parity of the error correction block, and selectively declaring the error correction impossible with reference to the position information where the eraser is declared. Characterized in that,

In addition, the error correction block decoding method of the high-density optical disc according to the present invention detects syndrome check values for a plurality of syndrome check parities recorded in the data column in the horizontal direction among the error correction blocks, and also in the horizontal data stream. Detecting a value of the recorded sync byte; An error occurrence position having a non-zero value in the detected syndrome check value continuously occurs in syndrome check parity recorded at a predetermined interval in the corresponding data string, or the value of the detected sync byte is a preset unique value. Declaring an eraser when the error occurrence position having no value and the error occurrence position having a non-zero value in the syndrome check value are continuously generated; And performing an error correction operation on a longitudinal data string using the outer parity of the error correction block, and selectively declaring the error correction impossible with reference to the position information where the eraser is declared. It is characterized by.

Hereinafter, a preferred embodiment of an error correction block encoding and decoding method of a high density optical disc according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 conceptually illustrates an encoder to which an error correction block encoding method of a high density optical disc according to the present invention is applied, wherein user data input to the encoder 100 has a predetermined recording size. A data block generator 10 for generating a data block, a PO generator 11 for generating an outer parity for the data block, and a syndrome check parity (SCP: Syndrome) for the data block. SCP generation unit 12 for generating a check parity) may be included.

On the other hand, in the encoder 100, as shown in Figure 4, by encoding the user data to generate an error correction block (ECC Block) having a recording size of 'N ₁ XN ₂ ' bytes, the error correction The code rate of the block is determined by subtracting syndrome check parities (SCPs) for erasure declaration from user data blocks of 'K ₁ X (K ₂ XL)' bytes, followed by outer parity (PO) of 'OP' bytes. Divided by the total record size of 'N ₁ XN ₂ ' bytes with one byte syndrome check parity (SCP), ie '((K ₁ X (K ₂ XL)-SCP) / (N ₁ XN ₂ )' Is the code rate of.

The maximum error correction capability of the error correction block is 'N ₂ X OP' bytes, and the error correction block includes an inner code consisting of RS (I _n + 1, I _n , 2) and an inner code. The error is corrected by an outer code consisting of RS (N ₁ , K ₁ , N ₁ -K ₁ +1).

In the encoder 100, K ₁ bytes are generated in the longitudinal direction as described above, and (K ₂ XL) bytes are generated in the horizontal direction to form a data block, and then RS (N ₁ , K ₁ , N _The outer parity PO is generated by the number of 'OP (= N ₁ -K ₁ )' bytes by ₁ -K ₁ +1), and by RS (I _n + 1, I _n , 2), FIG. As shown in FIG. 4, one-byte syndrome check parities (SCPs) are generated using an I _n information byte (I) string selectively in a block of K ₂ bytes.

On the other hand, the number of I _n is an important factor in determining the error correction capability for random error and burst error, for example, the number of bytes of I _n and the number of bytes of K ₂ . If the same, the error detection capability is improved, but the error correction capability is lost, and the number of bytes of K ₂ can be variably adjusted for the code rate adjustment.

In addition, the interval and the number of information bytes (I _{1 to} I _n ) in the K ₂ data block for generating the syndrome check parity (SCP) may be variably adjusted, and recording of the 'N ₁ XN ₂ ' bytes. The final error correction block having the size is read out sequentially based on the data stream in the lateral direction.

FIG. 5 conceptually illustrates a decoder to which an error correction block decoding method of a high-density optical disc according to the present invention is applied. The decoder 200 stores a data string read out based on a horizontal data stream. SCP calculation unit for declaring an erasure after receiving an error correcting block and performing an error detection operation by using information byte I and syndrome check parity (SCP) included in the horizontal data stream. (20), PO calculation unit 21 for performing an erasure decoding operation using the position information and outer parity PO in which the erasure is declared, and user data error-corrected by the erasure decoding operation. The data block generator 22 for generating a block may be included.

If the other hand, when the decoder 200 in the error correction block of the data sequence in the horizontal direction is configured as described above with reference to Figure 4 the received read, using the data string of +1 K ₂ bytes, RS ( A syndrome check operation is performed by an inner code consisting of I _n + 1, I _n , 2), and the syndrome check value is zero after repeating the syndrome check operation on the data column in the horizontal direction. If not), it is determined that an error has been detected in the data block. If the syndrome check value is zero, it is determined that no error has been detected in the data block.

As a result of the determination, when the error occurrence position is continuously generated in the syndrome check parity included in the data string on the same line, the erasure is declared for the data string currently decoded by the syndrome check operation.

That is, if the error occurrence position detected by the syndrome check by the inner code of RS (I _n + 1, I _n , 2) occurs continuously in the syndrome check parities included in the data string on the same line, the current syndrome You will declare an erasure for check parity and for syndrome check parity before or after it.

In addition, the decoder 200 performs erasure decoding on an outer code by using the erasure position information obtained through the above process, and the erasure decoding using the outer code is' (erase declaration). Number) + (2 X number of random errors) < = (N ₁ -K ₁ ) 'Only if the condition is satisfied, otherwise, error correction is declared and decoded as it is.

6 and 7 illustrate a first specific embodiment of an error correction block of a high density optical disc encoded and decoded according to the present invention, and the encoder configured and operated as described above with reference to FIGS. 3 and 4. The error correction block generated by (100) may have a write size of '246 X 312' bytes, wherein the code rate of the error correction block is '0.854', and the maximum error correction capability is '9984'. Byte, and the error correction block is error corrected by an inner code consisting of RS (3, 2, 2) and an outer code consisting of RS (246, 214, 33).

The encoder 100 generates 214 bytes in the longitudinal direction using the Galloa field GF 2 ⁸ , generates 308 bytes in the lateral direction, and configures a data block. Then, the RS (246,214) is used. The outer code of (33) generates 32 bytes of outer parity PO corresponding to 214 bytes.

In the encoder 100, as shown in FIG. 6, a syndrome check byte of one byte size corresponding to two bytes of information bytes I by an inner code of RS (3, 2, 2) is shown. After generating the (SCP) four times, the error correction block of the '312 X 246' byte size generated through the above process is sequentially read out based on the horizontal data stream.

On the other hand, in the decoder 200, when the horizontal data string is read out from the error correction block, three bytes of information bytes and syndrome check parity are used among the data strings within a 78 (77 + 1) byte interval. By detecting and confirming whether the syndrome check value is zero, the syndrome check operation is repeated four times for the data column in the horizontal direction to declare the erasure.

For example, as shown in FIG. 7, the error check position where the syndrome check value is detected other than zero by repeatedly performing the syndrome check operation on the data column in the horizontal direction is on the same line. When consecutive occurrences occur in the syndrome check parity included in the data column, an erasure is declared for an information block between the syndrome check parities, and the error occurrence position occurs solely in any one syndrome check parity. Does not declare erasers.

In addition, the decoder 200 performs an erasure decoding operation by an outer code by using the position information where the erasure is declared through the above process, wherein the erasure decoding operation using the outer code is performed by ' It is executed only when the condition of (number of erasure declarations) + (number of 2 X random errors) ≤ 32 'is satisfied. Otherwise, error correction is declared.

Therefore, since the erasure declaration is made using only the syndrome check, the decoding operation becomes simpler, the number of data constituting the inner code is reduced, the encoding and decoding time are shortened, and the decoding and erasure declaration on a block basis This makes the burst error stronger and increases the outer parity to further improve the maximum error correction capability.

8 to 10 show a second embodiment of an error correction block of a high-density optical disc that is encoded and decoded according to the present invention. The error correction block generated according to the second embodiment of the present invention is shown in FIG. It has a recording size and code rate as described above with reference to the reference, and in the encoder 100, repeating the operation of generating syndrome check parity (SCP) of 1 byte for a block of data K ₂ bytes L times In this case, by using all I information byte strings consecutively recorded in the K ₂ byte data block, 1 byte syndrome check parity (SCP) is generated.

Meanwhile, the number of bytes of K ₂ may be variably adjusted for code rate adjustment, and the final error correction block having a recording size of 'N ₁ XN ₂ ' bytes may be based on a data column in a horizontal direction. Read sequentially, for example, as shown in FIG. 9, the error correction block generated by the encoder 100 may have a write size of '197 X 390' bytes, wherein the error correction The code rate of the block is '0.853', the data block size is '65664' bytes, the maximum error correction capability is '10140' bytes, and the error correction block is RS (65,64,2). The error correction is performed by an inner code consisting of) and an outer code consisting of RS (197, 171, 27).

The encoder 100 generates 171 bytes in the longitudinal direction, generates 384 bytes in the lateral direction, forms a data block, and then stores 171 bytes in the outer code of the RS (197, 171, 27). The corresponding 26 bytes of outer parity PO are generated.

Further, in the encoder 100, as shown in FIG. 9, a syndrome check byte of one byte size corresponding to information bytes I having a size of 64 bytes by an inner code of RS (65, 64, 2) is shown. After generating the (SCP) six times, the error correction block of the '390 X 197' byte size generated through the above process is sequentially read out based on the horizontal data stream.

On the other hand, in the decoder 200, when the horizontal data string is read out from the error correction block, the decoder 200 uses the 65 bytes of information bytes and syndrome check parity to input the inner code of the RS (65, 64, 2). By detecting and confirming whether the syndrome check value is zero, the syndrome check operation is repeated six times for the data column in the horizontal direction to declare the erasure.

For example, as illustrated in FIG. 10, an error occurrence position at which a syndrome check value other than zero is detected is repeatedly performed by repeatedly performing a syndrome check operation on a data column in a horizontal direction. When consecutive occurrences occur in the syndrome check parity included in the data column, an erasure is declared for an information block between the syndrome check parities, and the error occurrence position occurs solely in any one syndrome check parity. Does not declare erasers.

In addition, the decoder 200 performs an erasure decoding operation by an outer code by using the position information where the erasure is declared through the above process, wherein the erasure decoding operation using the outer code is performed by ' It is executed only when the condition of (Number of Eraser Declarations) + (2 X Number of Random Errors) ≤ 26 'is satisfied. Otherwise, error correction is declared.

11 to 13 illustrate a third embodiment of an error correction block of a high density optical disc encoded and decoded according to the present invention. In the encoder 100, as described above with reference to FIG. An error correction block (ECC Block) having a write size of N ₁ XN ₂ 'bytes is generated and a syndrome check parity (SCP) for erasure declaration is included in the user data block, where the user data is recorded. In the block, as shown in Fig. 11, Sync bytes used for erasure declaration are included and recorded at predetermined intervals.

Meanwhile, the sync byte has a fixed value of 1 byte or more. For example, the error correction block may have a write size of '242 X 312' bytes, as shown in FIG. In this case, the code rate of the error correction block is '0.852', the data block size is '65664' bytes, the maximum error correction capability is '9920' bytes, and the error correction block is RS (39). Error correction is performed by an inner code consisting of (38, 2) and an outer code consisting of RS (248, 216, 33).

The encoder 100 generates 216 bytes in the longitudinal direction, generates 304 bytes in the lateral direction, configures a data block, and then generates 216 bytes using an outer code of RS (248, 216, 33). The corresponding 32-byte outer parity PO is generated.

In addition, the encoder 100 generates one byte syndrome check byte (SCP) eight times every 38 byte intervals by an inner code of RS (39, 38, 2), and generates a preset fixed value. After generating and recording the sync byte having a size of 1 byte as shown in FIG. 12, the error correction block having a '242 X 312' byte size generated through the above process is generated. Based on this, the readout is sequentially performed.

On the other hand, in the decoder 200, when the horizontal data string is read out from the error correction block, the RS (39, 38, 2) of the RS (39, 38, 2) is used by using 39 bytes of information bytes and syndrome check parity (SCP). In addition to detecting and confirming whether a syndrome check value by an inner code is zero, it is also checked whether a sync byte of one byte detects a preset fixed value, wherein the syndrome check operation and the sync byte are performed. By performing a check operation, the eraser is declared.

For example, as illustrated in FIG. 13, an error occurrence position at which a syndrome check value other than zero is detected by a syndrome check operation on a data column in a horizontal direction is included in the data line on the same line. In the case of successive occurrences in syndrome check parity, an erasure is declared for an information block between the syndrome check parities, and if the error occurrence position occurs solely in any one syndrome check parity, Will not declare.

In addition, when error detection occurs in the syndrome check parity adjacent to the sync byte without detecting the sync byte as a preset fixed value, the eraser is erased for the information block between the sync byte and the syndrome check parities. Will be declared.

Meanwhile, the decoder 200 performs an erasure decoding operation by an outer code by using the position information in which the eraser is declared through the above process. In this case, the erasure decoding operation using the outer code is' It is executed only when the condition of (number of erasure declarations) + (number of 2 X random errors) ≤ 32 'is satisfied. Otherwise, error correction is declared.

As mentioned above, preferred embodiments of the present invention are disclosed for the purpose of illustration, and those skilled in the art can improve and change various other embodiments within the spirit and technical scope of the present invention disclosed in the appended claims below. , Replacement or addition would be possible.

The error correction block encoding and decoding method of the high-density optical disc according to the present invention, which is constructed and configured as described above, generates a user data block having a predetermined recording size when performing the encoding operation of the error correction block. At least one of syndrome check parity, sync byte, and indicator flag for generating outer parity for the data column in the directional direction and declaring the erasure declaration for the data column in the lateral direction at predetermined intervals When the error correction block decoding operation is performed, the data is included in the user data block, and the eraser is declared with reference to whether an error occurs in at least one of syndrome check parity, sync byte, and indicator flag. In error correction block of next-generation high density optical disk, If there is a continuous burst error in the vertical direction or the longitudinal direction, the error correction error caused by the burst error can be minimized, and the error correction error caused by the random error can be effectively suppressed and the encoding And it is a very useful invention that can further improve the time required for decoding operation and the maximum error correction capability.

Claims (15)

Generating a user data block having a predetermined recording size; And The user data block includes a syndrome check parity for generating outer parity with respect to a longitudinal data string and declaring an erasure declaration for a horizontal data string at predetermined intervals. An error correction block encoding method of a high density optical disc, characterized in that it comprises two steps of recording at least one or more in the block. The method of claim 1, In the second step, a synchronization byte for generating the eraser declarations for the transverse data streams at predetermined intervals may be generated together with the syndrome parity and recorded in the user data block. An error correction block encoding method of a high density optical disc, characterized in that. The method of claim 2, And said sync byte has a unique value set in advance. The method of claim 1, The outer parity, the number of bytes in the longitudinal recording size (N ₁ XN ₂₎ of the entire error correction block (N ₁₎ and a number of bytes in the record size of the longitudinal direction of the user data block, which is determined by the (K ₁₎ An error correction block encoding method of a high density optical disc, characterized in that generated by the number of 'N ₁ -K ₁ ' bytes by 'RS (N ₁ , K ₁ , N ₁ -K ₁ +1)'. The method of claim 1, The syndrome check parity is an error correction block encoding of the high density optical disc, wherein the number of the predetermined intervals is generated by a plurality of information bytes and an inner code intermittently included within a predetermined interval among the horizontal data streams. Way. The method of claim 1, The syndrome check parity is an error correction block encoding method of a high density optical disc, wherein the number of the predetermined intervals is generated by information bytes and inner codes successively included within a predetermined interval among the horizontal data streams. . The method according to any one of claims 5 and 6, The inner code is 'RS (I _n + 1, I _n , 1 + 1)' by the number of bytes (I _n ) of information bytes included in the predetermined interval and the number of bytes (1) of the syndrome check byte. Error correction block encoding method of a high density optical disc, characterized in that determined by. Detecting syndrome check values for a plurality of syndrome check parities recorded in a data column in a horizontal direction among the error correction blocks; Declaring an eraser when an error occurrence position having a non-zero value in the detected syndrome check value is continuously generated in syndrome check parity recorded in a corresponding interval in the data column; And Performing an error correction operation on a longitudinal data string using the outer parity of the error correction block, and selectively declaring the error correction impossible with reference to the position information where the eraser is declared. An error correction block decoding method for a high density optical disc, characterized by the above-mentioned. The method of claim 8, And said step 2, if the detected error occurrence position occurs solely in syndrome check parity recorded at predetermined intervals in the data stream, the eraser does not declare an erasure. The method of claim 8, In step 3, an error correction operation is performed on the data string in the longitudinal direction using the outer parity of the error correction block, wherein '(number of erasure declarations) + (2 X random errors) ≤ (outer in the longitudinal direction). Parity byte count " ", wherein the error correction operation is performed. The method of claim 8, In step 3, an error correction operation is performed on the data strings in the longitudinal direction using the outer parity of the error correction block, wherein '(Eraser declaration number) + (2 X random error number) ≤ (Outer direction of the longitudinal direction). And error correction impossibility if the condition of parity bytes) is not satisfied. Detecting a syndrome check value for a plurality of syndrome check parities recorded in the data column in the horizontal direction among the error correction blocks, and detecting a value of the sync byte recorded in the data column in the horizontal direction; An error occurrence position having a non-zero value in the detected syndrome check value continuously occurs in syndrome check parity recorded at a predetermined interval in the corresponding data string, or the value of the detected sync byte is a preset unique value. Declaring an eraser when the error occurrence position having no value and the error occurrence position having a non-zero value in the syndrome check value are continuously generated; And Performing an error correction operation on a longitudinal data string using the outer parity of the error correction block, and selectively declaring the error correction impossible with reference to the position information where the eraser is declared. An error correction block decoding method for a high density optical disc, characterized by the above-mentioned. The method of claim 12, In the second step, if the detected error occurrence position occurs solely in the syndrome check parity recorded at predetermined intervals in the corresponding data string, or in the synchronization byte alone, the eraser is not declared. Error correction block decoding method of high density optical disc. The method of claim 12, In step 3, an error correction operation is performed on the data strings in the longitudinal direction using the outer parity of the error correction block, wherein '(Eraser declaration number) + (2 X random error number) ≤ (Outer direction of the longitudinal direction). Parity byte count " ", wherein the error correction operation is performed. The method of claim 12, In step 3, an error correction operation is performed on the data string in the longitudinal direction using the outer parity of the error correction block, wherein '(number of erasure declarations) + (2 X random errors) ≤ (outer in the longitudinal direction). And error correction impossibility if the condition of parity bytes) is not satisfied.