RU2488900C1 - Method of protection of digital information flows against media defects - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: method is proposed for protection of digital information flows against defects. Before recording onto a medium, the input flow of data is distributed among the blocks (B) and block groups (BG) with application of intra-block noise-immune data coding, defect-protection coding and addition of service codes to BG. The generated BG are recorded to the medium and reproduced immediately after recording. Further the delayed initial and counted BG are compared, and defective BG and defective B are detected. Further additional defect-protective coding of marked groups of delayed initial BG is carried out with account of values of appropriate defective B in the defective BG.

EFFECT: improved efficiency of protection of digital information flows against all and any size of primary defects of a medium and its all secondary and tertiary defects up to specified maximum size both separately and in their different combinations, increased reliability of recording and storage of information, extension of storage time of recorded information without loss of quality and accuracy of its reproduction and service life of media.

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Description

The invention relates to the field of protection of digital information flows from distortion caused by media defects, and can be used in measuring, computer and multimedia data recording and storage systems.

There is a method of protecting digital information flows from media defects, including the distribution of data prior to recording them on a medium in blocks, in-block noise-protective coding of data, and the detection of defects in the process of recording data on a medium and in the process of their reproduction from a medium (RF application 2001117205, class G11В 20 / 18, 2003).

The known method has several significant disadvantages. Firstly, when it is used, the continuity of recording and the sequential arrangement of the data stream on the medium are violated. Secondly, it does not contain defect-proof encoding of groups of data blocks, and the data streams are protected from primary and secondary defects in the method by means of a complex defect management system, including the operation of allocating on the media a special defect control area designed to replace defective areas with replacement areas , a special general-purpose area for storing application drivers with which defects are monitored, and a primary and / or secondary defect table with addresses de ektnyh and corresponding replacement areas and a computer configured to control operations of realization defects using defect tables. Thirdly, the method does not protect the streams of the main data recorded on the medium, as well as the replacement data and data of the defect management system from tertiary defects that inevitably arise during subsequent reproduction of the recorded information.

There is also a method of protecting digital information flows from media defects, including the distribution of data before they are written to the media in blocks and groups of blocks with dimensions set taking into account the dimensional characteristics of media defects, intrinsic noise-protective coding of data, defect-protection coding and addition of service codes for groups of data blocks, recording source encoded and supplemented groups of data blocks on the media and their control playback immediately after recording with temporary storage with of the finished and corresponding source groups of data blocks, detection of defective blocks during playback of data from the medium in the delayed read groups of data blocks and restoration of the values of the defective data block in the defective data block group using its remaining data blocks (Pat. RF 2351025, class G11B 20/18, 2009).

However, this method also has several disadvantages that significantly reduce the effectiveness of protecting digital information from media defects. Thus, in the known method, to protect the recorded data from primary and secondary defects detected immediately after data recording, the operation of replacing two blocks of the original block of the detected defective block with conditional positions in the next group of data blocks prepared for recording, that is, blindly, without knowledge of the possible the presence, location and size of the defect in areas of the upcoming recording. For this reason, not all consecutive primary and secondary defects can be corrected using the defective block chains used in the known method. Secondly, the substitution in the method is carried out if there are more than two defective blocks in the defective group, as a result of which the group of data blocks with two correctable defective blocks is unprotected from tertiary defects during subsequent reproductions of data streams. Thirdly, the replacement of two blocks even in a defect-free next prepared for recording group of data blocks is equivalent to the appearance of two defective blocks in it, which also means the complete insecurity of such a group from tertiary defects.

Of the known methods for protecting digital information streams from media defects, the closest in essence to the proposed method is a method for protecting digital information streams from media defects, including distributing the stream prior to recording on the medium over data blocks and groups of data blocks with dimensions established taking into account the dimensional characteristics of media defects , intra-block noise-protective coding, defect-protective coding and addition of data block groups with service codes, recording encoded and supplemented x groups of data blocks on the medium and their control playback immediately after recording with temporary storage of the read and the original groups of data blocks and the detection of defective read groups of data blocks, additional defective coding by establishing for each defective block a group of a specified number of auxiliary delayed source groups of data blocks, redefinition of the values of their defect-proof blocks taking into account the initial value of the defective block and the formation of signs in their service codes x and the address data of the defect (Pat. RF 2428753, cl. G11B 27/10, 2011).

However, this known method also has several disadvantages that significantly reduce the effectiveness of protecting digital information streams from media defects.

So, firstly, in the method, accurate knowledge about primary defects is obtained only at short working intervals prior to re-recording the current fragments of the stream of groups of data blocks to the same sections of the medium, without knowledge of the presence, location and size of subsequent primary defects, and how the size of the working interval is fixed and taking into account a given averaged for all carriers of a certain type of maximum size of the corrected primary defects, it is possible to detect rvichnogo defect or group of closely spaced from the primary defect exceeding a predetermined maximum size, which causes distortion of uncorrectable information. Secondly, in the known method there is no control of secondary defects after a working recording, as a result of which part of the secondary defects that were not detected during the primary recording, goes into the category of tertiary, detected during playback, but having a size exceeding the specified maximum size of the corrected tertiary defects, and therefore not amenable to correction during playback. Thirdly, the inclusion of any auxiliary group of data blocks from among the group of blocks subjected to additional defect-protection coding to protect against a primary defect, on a secondary defect not detected during recording also leads to uncorrectable distortions of the information during its reproduction.

The objective of the invention is to ensure the protection of digital information flows during their continuous recording on the media, storage and continuous reproduction from all primary defects regardless of their actual size and location on the medium, as well as from all secondary and tertiary defects up to their specified maximum sizes individually and in their various combinations, due to preliminary obtaining accurate and complete knowledge about the presence, size and location of primary defects throughout the specific carrier and use zovaniya this knowledge to determine the individual size range digital delay data stream on the recording medium, sufficient for additional proactive. defect protection coding of the original groups of data blocks with protection against the worst combination of heterogeneous defects: the identified primary defect with the largest size, possible one or more secondary defects with a given maximum size and tertiary defects of a given maximum size, for example, one in each group of auxiliary groups of blocks, with using the total correction potential of defect-free source groups of data blocks on the delay interval.

The technical result of the invention is a significant increase in the efficiency of protection of digital data streams during their continuous recording, storage and reproduction from primary, secondary and tertiary defects of media both individually and in various combinations thereof, thereby improving the reliability of recording and storage of digital information, extending the time frame storage of recorded information without loss of quality and accuracy of its reproduction and the life of the media.

The technical result is achieved in that in a method for protecting digital information streams from media defects, including distributing the stream prior to recording on the medium across data blocks and groups of data blocks with dimensions set taking into account the dimensional characteristics of the media defects, intrinsic noise-protective coding, defect-proof coding and addition with service codes groups of data blocks, recording encoded and supplemented groups of data blocks on a medium and their control playback immediately after recording from temporary storage of the read and the original groups of data blocks and the detection of defective read groups of data blocks, additional defective coding of the defective read group of data blocks by establishing for each of its defective block groups of a specified number of auxiliary delayed source groups of data blocks, redefining the values of their defect-proof blocks taking into account the original values of the defective block and the formation in their service codes of symptom and address data about the defect, according to the invention, about there is a recording on the carrier of a sequence of groups of test data blocks with a structure similar to the structure of coded and supplemented groups of digital data blocks, control playback of groups of test data blocks with the detection of primary defects and the formation of a control sequence of service attribute and address codes of defective block groups and defective blocks in them, determine for each primary defect, taking into account the number of blocks distorted by it and a given number of auxiliary groups of blocks per def The block size of the corresponding defect protection interval is set for each primary defect or group of primary defects closely spaced to each other, taking into account the size of respectively one or a group of their defect protection intervals, the specified maximum size of the corrected secondary defects, the number and location of defect-free groups of blocks before and after the defect, or defect groups the start and end addresses of the interval of preemptive additional defect protection coding, form codes with indicative and address data of the interval of preemptive additional defect protection coding and defect protection intervals included therein and supplement the control sequence of service codes with them, set the delay value for recording the stream of digital information on the media taking into account the value of the largest of the intervals of the preemptive defect protection coding and record the control sequence of service codes and the delay code recording on the media, before recording the stream of digital information is reproduced with n the carrier, the control sequence and write delay codes, delay, in accordance with the delay code value, the sequence of the formed groups of data blocks on the medium are recorded and the forward defect-protective coding is carried out in the delay interval in accordance with the current values of the control sequence service codes.

Figure 1 presents a structural diagram of a variant of the device for implementing the method, figure 2 presents time diagrams explaining the essence of the method.

The device for implementing the method comprises (Fig. 1) a control unit 1, a test sequence generator 2, a test sequence and input digital data distribution unit 3 for data blocks (B) and blocks for groups of data blocks (GB), block 4 of the inter-block interference protection coding , defect protection coding (DZK) and supplementing each GB with code groups for service data, recording unit 5, playback unit 6, unit 7 for detecting defective GB and defective B in them and generating indicative and address values x service codes, shaper 8 of the control sequence of service codes (UPSK), shaper 9 of the values of the attribute and address codes of the defect protection intervals (DZI) and intervals of the anticipated additional DZK, shaper 10 of the write delay code, block 11 recording delay, additional DZK and anticipatory additional DZK, unit 12 for detecting defective and auxiliary GBs, allocating and correcting service code values, block 13 for delaying the reproduced GB sequence and correcting their distortions, driver 14 the flow of digital information.

The control unit 1 is connected by the first (1Un), second (2Un) and third (3Un) control inputs, respectively, to the “Test”, “Record” and “Play” buses of the device, the first (1us), the second (2us), and the third (3us) , fourth (4us) and fifth (5us) installation inputs respectively to the buses “m _KG ”, “m _B ”, “m _KB ”, “D2 _MAX ” and “m _GB ” of the device, the first output (1) to the first control inputs (1 unit) of blocks 3, 4, 5, 6, 7 and formers 2, 8, 9 and 10, the second output (2) to the second control inputs (2 unit) of blocks 3, 4, 5, 6, 7 and to the control input ( 1Up) of block 11, the third output (3) to the third him to the control input (3Up) of block 6 and to the control inputs (1Up) of blocks 12, 13 and 14.

Shaper 2 output (1) is connected to the first information input (1i) of block 3, connected by the second information input (2i) to the input bus of the device, the first (1us) and second (2us) installation inputs to the buses "m _KG " and " m _B ”, respectively, and output (1) to the information input (1i) of block 4 connected to the first (1us), second (2us) and third (3us) installation inputs to the buses“ m _KG ”,“ m _B ”,“ m _KB ", respectively, and by output (1) to the first information inputs (1i) of unit 5 connected by a second information input (2i) to the output (1) of driver 8, by a third formation input (3i) to the output (1) of the shaper 10 and the fourth information input (4i) to the output (1) of the block 11, and the output (1) to the bus "On the carrier" of the device. The output (1) of block 4 is also connected to the first information input (1i) of block 11, the second (2i) and third (3i) information inputs of which are connected respectively to the first output (1) of block 6 and the output (1) of block 7.

The playback unit 6 is connected by the information input (1i) to the device’s “C” bus, the second output (2) to the information input (1i) of the unit 7, the output (1) connected to the first information inputs (1i) of the drivers 8 and 9, and the third output (3) to the information inputs (1i) of blocks 12, and 13. Output (1) of the driver 9 is connected to the second information input (2i) of the driver 8 and to the first information input (1i) of the driver 10. Output (1) of the block 12 connected to the second information input (2i) of the block 13, connected by the output (1) to the information input do 9! and 0 of block 14, output (1) connected to the “Output” bus of the device.

Figure 2 shows; a) - an example of the distribution of the input stream of digital information (in the form of a sequence of information code groups (KG) with a fixed number of binary codes, for example bytes, conventionally depicted by vertical lines), distributed over blocks (B) of m _KG code groups (in the example m _KG = 5 and each B includes 4 informational CTs and 1 control CCG) and groups of blocks (GB) of m _B informational B and m _DZB defect protection blocks (DZB) (the example shows one GB1 consisting of m _B = 4 informational and m _DZB = 1 of one DZB) and additions of each GB service by codes (SK); in the figure, the CGs are highlighted with curly brackets and the corresponding inscriptions below, and B, DZB, GB and SK are marked with lines with arrows and corresponding inscriptions; b) - an example of a fragment of a numbered sequence of encoded and supplemented groups of test or input digital data blocks GB1-GB65 recorded on a formatted medium (in the figure, each GB is conventionally represented by the service part as a vertical section of a larger straight line and a group of information, for example, the first four B, and one DZB in the form of vertical segments of a straight line of a smaller size); GB numbers hereinafter are conventionally considered GB addresses; vertical rectangles in GB2 and GB42 and inscriptions above them are conventionally indicated respectively the sign of P (n _DRM 1) _START . and the address A (GB2) of the beginning and the sign of P (n _CRM 1) _KOH . and address A (GB42) of the end of the first interval n _CRM.DZK 1 of the anticipated additional spare wheel bracket for protection against a group of primary defects D1 ₁ -D1 ₃ closely spaced to each other, marked with a stroke and hatching; n _DZI (D1 ₁ ), n _DZI (D1 ₂ ) and n _DZI (D1 ₃ ) - defect protection intervals (DZI) with protection respectively from the detected primary defects D1 ₁ , D1 ₂ , and D1 ₃ ; n _DZI (D2 _MAX ) - defect protection interval with protection against possible secondary defects D2 _MAX on previous DZI; n _{DZI REZ} · (D2 _MAX ) - reserve DZI for protection against a possible second D2 on previous DZI; n _DZI (D1 ₄ ) - defect protection interval with protection against the primary defect D1 ₄ , marked by stroke and hatching; P (n _UPR.DRZK 1) _N and A (GB43) _N - sign and address of the beginning and P ( _UPR.ZZK 1) _K and A (GB65) _K - sign and address of the end of the second interval n _UPR.ZZK 2 of the anticipated additional spare wheel bracket ; c) a detailed example of the implementation in the process of recording a GB sequence of digital data of the form Fig. 2, b preempting the actual detection of D1 _{1 of} an additional remote sensing device on a DZI (D1 ₁ ) with protection from D1 ₁ (in Fig. 2, highlighted by a stroke and hatching) with Address A (GB30); the operations of entering the characteristic and address data about the defect in the service CG of the corresponding pairs of auxiliary GBs are conventionally shown in Fig. 2, in lines with arrows from the defective blocks DB1-DB4 of the defective GB30 to the corresponding service CG conventionally shown with shaded large rectangles and corresponding inscriptions, and operations redefinition of the RMS values of the corresponding pairs of auxiliary GBs is conditionally marked by the dimming of the short straight line segments representing them; D2 ₁ - secondary defect (marked by a stroke and hatching) detected in the recording mode as a result of control playback immediately after recording a subsequence of pairs of auxiliary GBs on n _DZI (D1 ₁ ); the crosses are conventionally marked blocks distorted by tertiary defects, the appearance of which is possible in the playback mode sequence GB; d) - an example of the implementation in recording mode of an additional spare spare wheel bracket (D2 ₁ ) for protection against D2 ₁ (shown in Fig. 2, c) in the prescribed _{remote sensing} n n _DZI (D2 _MAX ) as a part of the interval n _UPR.DZK 1; all operations of the spare wheel bracket (D2 ₁ ) in Fig. 2, d are similar to the operations shown in Fig. 2, in the spare wheel bracket (D1 ₁ ); blocks distorted in the playback mode with tertiary defects are also conditionally marked with crosses.

A method for protecting digital information streams from media defects includes a set of operations that implement special modes for testing a medium, recording digital data streams on a medium and reproducing them from a medium, and is carried out as follows.

In the test mode of the medium, the test signal supplied to the first control input of the control unit 1 and the corresponding control pulses from its first output in the former 2 forms a test sequence of codes similar to the input sequence coming from the former 2 to the first information input of the block 3 in which, in accordance with the established values of m _KG and m _{B, the} test sequence is divided into B with m _KG KG and GB with m _B B, intrablock interference protection coding is performed, e.g. an example, by forming control KG in B (in Fig. 2, a one KKG in each B), and from the output of which the test sequence of GB is fed to the information input of block 4, in which the defective encoding (DZK) of GB is performed by forming and additions to each GB with the established number m of _{DZB of defect} protection blocks (RZB) (in the example in Fig. 2, a, one of the DZB) and complement the GB with service codes. The structure of the generated test GB is conditionally presented in Fig. 2, a and is similar to the GB structure of the input digital data.

The choice of parameter values m _KG and m _B , taking into account the dimensional characteristics of the flows of primary D1, secondary D2 and tertiary defects D3 in the proposed method is significantly simplified and refined in comparison with known methods, in particular, with the prototype method. So, instead of setting a deliberately inaccurate maximum size D1 _MAX averaged for all carriers of a certain type, the corrected primary defects in the proposed method obtain accurate data on the sizes and addresses of all primary defects of each carrier and provide proactive protection against them. The simultaneously obtained data on the size and location of defect-free intervals between primary defects can significantly increase the established maximum size D2 of the _{MAX of} corrected secondary defects up to the largest size of primary defects on the carrier. The establishment of the maximum size D3 of the _{MAX of the} corrected tertiary defects imposes, as in the known methods, a restriction only on the minimum size of the data block.

From the output of block 4, a sequence of test GBs of the form Fig. 2, b (GB addresses are conventionally represented by their numbers from 1 to 65) are fed to the first information input of block 5, with which it is recorded on a marked media. Immediately after recording the GB using block 6, they are reproduced, decrypted and brought back to the original, before recording, view of Fig. 2, b. From the first output of block 6, the GB sequence is fed to the information input of block 7, in which, by comparing read GBs with temporarily delayed initial test GBs, defective GBs are sequentially detected (GB30, GB32, GB34, and GB49 in Fig. 2 b) and defective B in them (in Fig. 2, b are marked with a stroke and hatching) and form the corresponding values of the characteristic P (D1 ₁ ), P (D1 ₂ ), P (D1 ₃ ), P (D1 ₄ ) and address A (GB30: B1- B4), A (GB32: B2-B4), A (GB34: B2-B4) service codes, at the corresponding moments, coming from the output of block 7 to the first information input of the shaper, 8, in which a control sequence of service attribute and address codes of defective GB and defective B is generated in them, updated every time a new primary defect is detected, in the following form: P (D1 ₁ ), A (GB30: B1-B4); P (D1 ₂ ), A (GB32: B2-B4); P (D1 ₃ ), A (GB34: B2-B4); P (D1 ₄ ), A (GB49: B2-B4); etc. At the same time, the indicated characteristic and address data from the output of block 7 are fed to the information input of the shaper 9, in which, firstly, for each primary defect, taking into account the number of B distorted by it and a given number m _GB (in the example m _GB = 2) of auxiliary GB for one defective B the size of the corresponding defect protection interval, i.e., n _DZI (D1 ₁ ) = 4 × 2 = 8B, n _DZI (D1 ₂ ) = 3 × 2 = 6B, n _DZI (D1 ₃ ) = 3 × 2 = 6B and n _DZI (D1 ₄ ) = 3 × 2 = 6B; secondly, the known addresses of the defects determine the degree of their proximity to each other and, if the distance between some of them does not exceed a given value (for example, no more than one GB), then consider a group of such defects (in the example, a group of D1 ₁ , D1 ₂ and D1 ₃ ) as a whole; thirdly, to protect against a possible secondary defect D2 _MAX in the mode of subsequent working recording, the interval of the anticipatory spare wheel bracket is prudently supplemented with a spare defect protection interval P _DZI (D2 _MAX ); fourthly, in the presence of a sufficient number of defect-free GBs in the vicinity of the defect (group of defects), one or more backup DZI n _{DZI, REZ} . (D2 _MAX ) can be provided as part of the anticipatory DZK interval to protect against an unlikely but possible second secondary defect (all the indicated DZI in Fig. 2, b are marked with arrows and corresponding inscriptions); fifthly, for each single primary defect (in example D1 ₄ ) or a group of primary defects (in example D1 ₁ , D1 ₂ and D1 ₃ ), the values of the attribute and address codes of the beginning and end of the intervals of the anticipated additional spare wheel bracket are formed, respectively, or for a separate primary defect (in Fig. 2, b - P (n _DRM 2) _START and A (GB43), P (n _DRM 2) _KON. and A (GB65)), or for a group of closely spaced primary defects (in Fig. 2, b - P (n _CRM 1) _KL and A (GB2), P (n _CDM 1) _KON. and A (GB42)).

From the output of the shaper 9, the indicative and address codes enter the block, 8 for supplementing the indicative and address codes of the corresponding primary defects already existing in the control sequence. As a result of the test mode, in block 8, the following (within the framework of the considered example) receive the augmented control sequence of feature and address codes:

P ₁ (D1 ₁ , D1 ₂ and D1 ₃ ): A, ₁ (GB30: B1, B2, B3, B4),

A2 (GB32: B2, B3, B4),

A3 (GB34: B2, B3, B4);

P (n _{UPR, spare wheel bracket} 1) _START : A (GB2);

P (n _DZI (D1 ₁ )): A (GB2, GB6, GB3, GB7, GB4, GB8, GB5, GB9);

P (n _DZI (D1 ₂ )): A (GB10, GB13, GB11, GB14, GB12, GB15);

P (n _DZI (D1 ₃ )): A (GB16, GB19, GB17, GB20, GB18, GB21);

P (n _DZI (D2 _MAX )): A (GB22, GB26, GB23, GB27, GB24, GB28, GB25, GB29);

P (n _DZI.REZ. (D2 _MAX )): A (GB35, GB39, GB36, GB40, GB37, GB41, GB38, GB42);

P (n _DRM 1) _KON. : A (GB42).

P ₂ (D1 ₄ ): A (GB49: B2, B3, B4);

P (n _UPR.DZK 2) _START. : A (GB43);

P (n _DZI (D1 ₄ )): A (GB43, GB46, GB44, GB47, GB45, GB48);

P (n _DZI (D2 _MAX )): A (GB50, GB54, GB51, GB55, GB52, GB56, GB53, GB57);

P (n _{DZI, RES.} (D2 _MAX )): A (GB58, GB62, GB59, GB63, GB60, GB64, GB61, GB65);

P (n _STR. 2) _KOH. : A (GB65).

From the output of the shaper 9, the feature and address codes also go to the shaper 10, in which the sizes and units of the anticipatory spare wheel bracket determine their sizes in GB units using the signs and addresses of the start and end of the remote control, taking into account the largest size (in the example, the largest size is 41GB for Interval n _{CRM control} 1) the value of n _REF. recording delays exceeding the set value, for example, by n _DZI (D2 _MAX ), the largest size, and form the binary code of the corresponding number of GB.

From the outputs of the shapers 8 and 10, the control sequence and the write delay code are supplied to the second and third information inputs of block 5, respectively, with the help of which they are recorded several times for reliability several times to predetermined media locations.

In the recording mode, the stream of digital information received on the bus “Input” of the device, by the signal “Record” and the corresponding control pulses, from the second output of block 1 using block 6 reproduces the control sequence and code delay recording from a specified location of the media coming from its first output to the second information input of block 11, in which they are stored during the entire recording mode. Using blocks 3 and 4, the digital stream is converted, as in the "Testing" mode, in accordance with the set values of m _KG , m _B and m _RPS into a GB sequence of the form Fig. 2, a supplied to the first information input of block 11, c which compares the current addresses of incoming GB with the address of the first defective group of GB30 in the control sequence corresponding to the first symptom of defect P ₁ (D1 ₁ , D1 ₂ and D1 ₃ ), and as soon as the specified addresses match, the values of its blocks B1-B4 become available, defective D1 ₁ for subsequent recording on the medium. After this, the sequential execution of the commands of the above control begins (Sequences of service codes: in the service KG GB2, the values of the attribute P (n _DRC 1) _START and the sign P (n _DZI (D1 ₁ )) are entered, according to which the standard procedure of the additional spare wheel (D1 ₁ ), presented in expanded form in Fig. 2, c and including the operations of writing values of characteristic and address data, for example, P (D1 ₁ ) and A (GB30: B1), into service codes of auxiliary GB2 and GB6, and also redefinition of their DZB by group summation according to the established the corresponding module, the values of B1 to the values of both remote sensing, and so on; according to the signs P (n _DZI (D1 ₂ )) and P (n _DZI (D1 ₃ )), similar standard procedures for an additional DZK (D1 ₂ ) and DZK ( D1 ₃₎ on the basis of n (n _DZI (D2 _MAX)) and P _(. n _{DZI, RES} (D2 _MAX)) is carried out either pass steam provided GB and auxiliary recording in the last interval GB42 _UPR.DZK 1 n P feature (. n _UPR.DZK 1) _KOH its end -. in the absence of already recorded and subjected to the control playback preceding DZI secondary defect, or as shown in the example of Figure 2, z is carried Art the standard procedure for additional spare parts and accessories (D2 ₁ ) with the inclusion of characteristic and address values in the service KG auxiliary GB24-GB29 and the corresponding overrides of the values of their remote sensing.

When the coincidence GB49 current address on the input unit 11 to a sign P (D1 ₄₎ and GB49 next location of the defect, like in the previous case, are entered into service CG GB43 sign P (n _UPR.DZK 2) _START. the beginning of the second interval of pre-emptive remote sensing, carry out the procedure for an additional remote sensing in the interval P _DZI (D1 ₄ ) and, in the absence of secondary defects, skip the intervals P (n _DZI (D2 _MAX )) and P (n _{DZI, RES.} (D2 _MAX )) and enter in GB65 of the interval n _UPR.DZK 2 (the value of the attribute P (n _Upr.dzk 2) _KON . its end.

So; Thus, as a result of the execution of the recording mode of the GB sequence of input digital data onto the storage medium, data of the control sequence of service codes providing GB protection. from all, primary and from previously detected during test recording, parts of secondary defects turn out to be embedded in the tagged defect-free GB of the sequence of GB of input digital data recorded on the medium.

In the playback mode of the data stream from the medium by the “Playback” signal supplied to the third control input of the control unit 1, and by the corresponding control signals from its third output. with the help of block 6, the control sequence is reproduced first. the service code sequence and the recording delay code coming from the third output of block 6 to the information inputs of blocks 12 and 13 to be stored for the entire data playback time, after which the GB stream is reproduced. In block 12, the values of the characteristic and address service codes in reproducible GBs are extracted, their authenticity is checked by comparing with, the values of the corresponding service codes of the control sequence and, in cases of distortion of the values of the read service codes, correct their values and also detect defective GB and defective B in them distorted by primary, secondary and tertiary defects, and form the values of feature and address service codes necessary for their recovery.

In block 13, the sequence of reproduced GBs arriving at its first information input is delayed by the number of GBs set by the value of the delay code and, by the indicative and address signals from the output of block 12 to its second information input, the values of defective B are restored to distorted primary, secondary or tertiary defects GB. In this case, the recovery of the defective B in the reproduced GB distorted by the secondary or tertiary defect located outside the interval of the pre-emptive additional spare wheel bracket is carried out, as in the prototype method, or using the group summation operation using the established module for the values of all the other B defective GBs (for example, GB1 on Fig. 2, c and GB21, GB22 and GB23 in Fig. 2, d) - in the case of a tertiary defect, or by operation, group summation over the established module of the values of all B, including the RIS with an overridden value, ogatelnoy GB sign and secondary defect address of the defect and its defect GB Used in service codes corresponding DZI (e.g., GB24, GB26 and GB28 interval DZI (D2 ₁₎ in Figure 2, g) - in the case of a secondary defect.

Within the reproduced intervals of the pre-emptive additional spare wheel bracket, marked with signs and addresses of the beginning and end (in the example in Fig. _2b , the interval n _CRM.CONTENT 1 is marked with the signs P (n _CRC.DZC 1) _START and P (n _CRM.COM 1) _KON. And with addresses A (GB2) and A (GB42), respectively, the interval n _KNOB.DZK 2 - with the signs P (n _KNOB.DZK 2) _START and P (n _KNOW.ZK 1) _KON. And addresses A (GB43) and A (GB65)), the restoration of the values of defective B is carried out differently in, depending on the types of defects and combinations of different types of defects. If there is one, primary defect (for example, D1 ₄ on n _{CRM. DPC} 2) or a group of primary defects (for example, D ₁ , D1 ₂ and D1 ₃ on n _{CRM. DPC} 1, the restoration of distorted GBs is carried out, for example, in the order of it is a DZI marked with signs of the beginning and addresses of auxiliary DGIs (for example, as shown in Fig. 2, for the interval n of _DZI (D1 ₁ )), and in the order of the groups of auxiliary GBs on each DZI. For each GB, groups of auxiliary GBs determine the initial value the corresponding defective B, the address data of which is contained in the service codes of the GB, and place the received initial value in accordance with the address data (for example, as shown in Fig. 2, c, the initial value of the defective block with address A defined in GB2 (GB30, B1) is entered in block B1 of group GB30).

If there is a pre-emptive remote sensing element in the interval (for example, by n _UPR.DZK 1), in addition to the group of primary defects of the secondary defect (for example, as shown in Fig. 2, c, the secondary defect D2 ₁ in the defect-protecting interval of n _DZI (D1 ₁ )), protection from which it was carried out in the “Record” mode by forming a special defect protection interval (in the example in Fig. 2, g n _DZI (D2 ₁ ) within the range of the anticipated DZK (in the example n _UPR.ZZK 1) of the spare interval n _DZI ( D2 _MAX )), first of all, restore defective B in GB, distorted secondary m defect (in the example in Fig. 2, into blocks B1, B2 and B3 in GB6), after which the defective ones are restored. B in GB distorted by the primary defect (in the example in Fig. 2, into blocks B1, B2, B3 and B4 in GB30). Each defective B is restored by group-by-group summation of the values of all Bs of each GB of the corresponding group of auxiliary GBs according to the established module and placement of the obtained initial value of defective B in accordance with the address data contained in the service codes of auxiliary GBs (for example, as shown in Fig. 2 , c and Fig. 2, d, determined from the values B of auxiliary GB24 and GB27, the initial value of the defective block with address A (GB6, B1) is entered in block B1 of group GB6). The combination of primary and secondary defects considered cannot be corrected using known methods.

If there are n _DZI (D1 ₁ ) and n _DZI (D2 ₁ ) in the defect protection intervals of the same interval, n _CRT.DZK 1 of the forward DZK together with the primary D1 ₁ and secondary D2 _1, respectively, of a tertiary defect, for example, in each group of auxiliary GBs ( in Fig. 2, c and Fig. 2, d, tertiary defects are conditionally marked by double strikethrough), first, the values of B distorted by the secondary D2 ₁ and primary D1 ₁ and defects are restored as described above, as a result of which the values of B involved in the redefinition become known DZB distorted tert chnymi subsidiary defect GB then carried defective recovery value B in each such group of auxiliary GB pogruppovogo by addition of the corresponding module installed becoming known value B, who participated in the auxiliary overridden DZB defective GB, and B values of all of GB except its defective B.

Thus, the application of the method of protecting digital data streams from media defects provides a significant increase in the efficiency of protecting digital data streams from all and any size of primary defects, secondary and tertiary defects up to a given maximum size thereof both individually and in various combinations thereof, and as a consequence, improving the reliability of recording and storing information, extending the storage time of recorded information without losing the quality of its reproduction and the life of the media.

Claims (1)

A method of protecting digital information streams from media defects, including distributing the stream prior to recording on the medium among data blocks and groups of data blocks with dimensions set taking into account the dimensional characteristics of the media defects, intrinsic noise protection coding, defective protection coding and addition of service codes to groups of data blocks, recording encoded and supplemented groups of data blocks on the media and their control playback immediately after recording with temporary storage of the read and the original opp data blocks and detecting defective read groups of data blocks, additional defective coding by establishing for each defective block a group of a specified number of auxiliary delayed source groups of data blocks, redefining the values of their defective block taking into account the initial value of the defective block and generating characteristic and defect address data, characterized in that the sequence of groups of test data blocks is recorded on a medium with the structure A swarm similar to the structure of coded and augmented groups, blocks of digital data, the control reproduction of groups of test data blocks with the detection of primary defects and the formation of a control sequence of service attribute and address codes of defective block groups and defective blocks in them, is determined for each primary defect taking into account the number of distorted blocks and a given number of auxiliary groups of blocks per defective block, the size of the corresponding defect protection interval is set for each a primary defect or a group of primary defects closely spaced to each other, taking into account the size of respectively one or a group of their defect protection intervals, the specified maximum size of the corrected secondary defects, the number and location of defect-free groups of blocks before and after a defect or group of defects, the starting and ending addresses of the interval of anticipatory additional defective encoding, generate codes with the characteristic and address data of the interval of proactive additional defect protection encoding and the defect-protection intervals included in it and supplement the control sequence of service codes with them, set the delay value for recording the digital information stream on the media taking into account the value of the largest of the intervals of the preemptive defect-protection coding, and write the control sequence of service codes and the delay code for writing to the media before recording the digital stream information is reproduced from the carrier codes of the control sequence and recording delays, delayed in accordance with delay code value entry sequence groups formed of data blocks on the carrier and carried on a preemptive delay interval defektozaschitnoe additional encoding according to the current values of service codes control sequence.

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