DE3125529C2 - Method for recoding a sequence of data bits into a sequence of channel bits, arrangement for decoding the channel bits coded according to this method and recording medium with an information structure generated according to this method - Google Patents

Abstract

The invention relates to the successive transmission of binary data over an information channel and, more particularly, to a method for encoding and decoding certain binary block codes. The invention particularly relates to cases where the information channel consists of an optical disk. In the case of block coding, blocks of, for example, m data bits are converted into blocks of n channel bits (n> m). The blocks of information bits obtained in this way are, for example, subject to the requirement of a (d, k) limitation. In (d, k) -limited sequences, the length of sequences of "zeros" is limited from a minimum number d to a maximum number k zeros between each pair of consecutive "irons". A disadvantage of this coding is that it has a non-negligible LF spectrum. According to the invention, a block of separating bits is included between each of the blocks of n information bits. In those cases where the format is not prescribed by the (d, k) requirement, the separating bits are selected in such a way that the low-frequency spectrum, and in particular the direct current component, is as low as possible.

Description

A. Background of the Invention
A (I) Field of the Invention

The invention relates to a method for recoding a sequence of data bits into a sequence of channel bits, the sequence of data bits being divided into consecutive blocks of m data bits each and these blocks being divided into consecutive blocks of (ti \ + n ₂ ) channel bits (m + n ₂ > m) are recoded and the blocks of channel bits each contain a block of n \ information bits and a block of n ₂ separating bits in such a way that successive blocks of information bits are separated by only one block of separating bits, two successive channel bits of a first type, dzs type » 1 ”, separated by at least d consecutive bits of a second type, of type“ 0 ”, and the number of consecutive channel bits of the second type is at most k , as well as to a demodulator for decoding the data bits encoded according to the method and to a recording medium with an information structure generated by this method with fol gen of channel bit cells.

In digital transmission, or in magnetic and optical recording-A-playback systems, this is the case information to be transmitted or recorded mostly in the form of a sequence of characters. These Characters together form the (often binary) alphabet. In the event that it is a binary alphabet (This alphabet is also represented by the characters "1" and "0"), one of the characters can be, for example the »1«, corresponding to the NRZ mark code on the magnetic disk, magnetic tape or optical Plate as a transition between two states of magnetization or two places of an optically active one Area can be specified. The other character, the "0", is due to the lack of such a transition set.

In practice, as a result of certain system requirements exist for the sequences of characters that occur allowed, restrictions. In some systems the requirement is that the sequence of characters is self-clocking. This means that the sequence of characters to be transmitted or recorded is sufficient Must have transitions to a clock pulse signal, which is necessary for detection and synchronization of the string to generate. Another requirement may be that certain strings be in the Information signal should be avoided because these sequences are used for special purposes, for example synchronization sequences, reserved. An imitation of the synchronization sequence by the information signal affects the uniqueness of the synchronization signal and thus its suitability for this purpose. One Another requirement can be that the transitions do not follow one another too quickly in order to avoid the intersymbol interference to restrict.

In the case of magnetic or optical recording, this requirement can also be related to the information density on the recording medium if the corresponding minimum time interval (T _m i ") of the signal to be recorded can be increased at a certain minimum distance between two successive transitions on the recording medium , the information density is increased to the same extent. The minimum bandwidth (B _m i ") that is required also depends on the minimum distance T _m j" between transitions

together.

When information channels are used that do not transmit direct current, as is usually the case with magnetic ones Recording channels is the case, this leads to the requirement that the character strings in the information channel have as little (or no) direct current component as possible.

A (1) Description of the prior art

A method of the type described at the outset is known from reference material D (I). The article refers to block encodings, assuming d-, k- or (d, ^ delimited g-valued blocks of characters and the blocks meet the following requirements:

(a) «/ -limited: two type“ 1 ”characters are represented by a sequence of at least one consecutive type "O" character running;

(b) ^ -limited: the maximum length of a sequence of consecutive characters of the type "0" is k.

A sequence of data bits is divided into immediately successive blocks of m data bits each. These blocks of m data bits are recoded into blocks of π information bits (n> m). Because η> m , the number of combinations with η information bits is greater than the number of possible blocks of data bits (2 ^m ). If the request of, for example, d-limited blocks of information ^{bits to be transmitted or recorded is made, the mapping of the 2 m} blocks of data bits to 2 ™ blocks of information bits (from a possible number of 2 "blocks) is selected in such a way that only those blocks of information bits are mapped that meet the requirement.

Table I on page 439 from reference material D (I) shows how many different blocks of information bits there are, depending on the length of the block (s) and the requirements placed on d. There are 8 blocks of information bits with a length η = 4 on condition that the minimum distance d = 1. Therefore, blocks of data bits with a length of m = 3 (2 ³ = 8 data words) could be represented by blocks of information bits with a length of η = 4, with two consecutive type "!" Characters in the blocks of information bits replaced by at least one type "0 «Characters are separated. The coding is then for this example (the ++ character stands for mapping the mapping of one block to the other and vice versa):

000 - 0000

001 - 0001
010 * »0010
011-0100

100 ~ 0101

101-1000
110-1001
111-1010

In the case of information words which follow one another in direct succession, however, in some cases the requirement made (in the example the ^ requirement) cannot be met without delay. In the said article it is proposed to insert separator bits between the blocks of information bits. In the case of (/ -limited coding, one block of separating bits with rf bits of the type "0" is sufficient. In the example given above with d = 1, only one separating bit (only one zero) is sufficient. Each block of 3 data bits is then coded with 5 (4 + 1) channel bits.

A disadvantage of this type of coding is that the proportion of low frequencies (including direct current) in the frequency spectrum of the stream of channel bits is quite high. Another disadvantage is that the coding converter (modulator, demodulator), and particularly the demodulator, is involved.
With regard to the first disadvantage, it should be noted that reference D (2) indicates that the

, 5 DC component of the (i.e. xy-limited coding can be limited by connecting the blocks of channel bits by a so-called inverting or a non-inverting element. The sign of the contribution of the current block channel bits to the DC component is thus chosen such that The direct current component of the preceding blocks of channel bits is reduced. However, this is a (d, / ^ limited coding whose blocks of information bits can immediately follow one another without impairing the (d, A / requirement, so that the addition of separating bits is unnecessary for this reason is

B. Summary of the Invention

The invention has for its object to provide a method of the type mentioned at the beginning for coding a sequence of data bits into a sequence of channel bits, which method improves the low-frequency spectrum properties of the signal to be derived from the channel bits and enables a simple demodulator
According to the invention, this object is achieved by the following steps:

1. Converting blocks of data bits containing m bits into blocks of information bits containing η bits;

2. The generation of several possible sequences of channel bits which each contain at least one block of information bits and one block of separating bits and which each contain the blocks of information bits, supplemented by only one of the possible bit combinations of the blocks of separating bits;
3. Determining the DC component of each of the possible sequences of channel bits that were determined in the previous step;

4. For each of the possible sequences of channel bits, determining the sum of the number of separating bits and the Number of consecutive information bits of the type "0" that immediately follow a bit of

the type "1" precedes and the sum of the number that follows a bit of the type "1" is the one part one of the blocks forms separating bits, and the sum of the number of separating bits and the number immediately successive information bits of type "0" which immediately precedes this block of separator bits and follows;

5. The generation of a first display signal for the sequences of channel bits for which the values of the sums determined in the previous step are greater than d and at most equal to k ;

6. Selecting the sequence of channel bits which will form the first indication signal of this sequence of channel bits which minimized the direct current component, have resulted from the sequences of channel bits, in which the first Display signal was generated.

C. Brief Description of the Drawings

Exemplary embodiments of the invention and their advantages are explained in more detail with the aid of the drawings. It shows

1 shows some bit sequences to explain an embodiment of the coding format according to the invention;

F i g. Fig. 2 shows some further embodiments of the format of the channel coding, as in the case of reduction the direct current component can be used according to the invention;

F i g. 3 is a flow chart of an embodiment of the method according to the invention;

Fi g. 4 shows a representation of a block of synchronization bits for use in the method according to the invention;

F i g. 5 shows an embodiment of a demodulator according to the invention for decoding the according to the invention coded data bits,

6 shows an embodiment of the means for detecting a sequence of synchronization bits after the Invention,

F i g. 7 shows an embodiment of a frame format for use in the method according to the invention. Corresponding elements in the figures are given the same reference symbols.

D. Reference material

(1) Tang, D. T., Bahl, L.R., "Block codes for a class of constrained noiseless channels," Information and Control Vol. 17, No. 5, Dec. 1970, pages 436-461.

(2) Patel, A. M., "Charge-constrained byte-oriented (0.3) code," IBM Technical Disclosure Bulletin, Vol. 19, No. 7, Dec. 1976, pages 2715-2717.

35 E. Description of the exemplary embodiments

F i g. 1 shows some bit sequences to explain the method for recoding a sequence of data bits (FIG. 1 a) into a sequence of channel bits (Ib). The sequence of data bits is divided into closed and consecutive blocks BD . Each block of data bits has m data bits. As an example, m = 8 is also chosen in the description and in the figures. However, the same applies to every other value of m. A block of m data bits Z? D generally contains one of 2 ^m possible bit sequences.

Bit sequences of this kind are less suitable for being recorded optically or magnetically directly, for different reasons. If two data characters of the type "1", which are recorded on the recording medium, for example as a transition from one direction of magnetization to the other or as a transition to a depression, follow one another directly, these transitions cannot be too close together because of the mutual influence . This limits the information density. At the same time, the minimum bandwidth B _{mm is} increased, which is required to transmit or record the bit stream if the minimum distance T _mm between successive transitions (B ″, i ″ = 1 / (2f _m , ″) is small another requirement, which is often placed on systems for data transmission and optical or magnetic recording is that the bit strings have sufficient transitions to recover from the transmitted signal a clock pulse signal can be generated with the synchronization. a word with m zero, the in in the worst case, preceded by a word that ends on a number of zeros and followed by a word that begins with a number of zeros, would jeopardize the clock pulse extraction.

To information channels that do not carry direct current, such as magnetic recording channels In addition, the requirement is that the data stream to be recorded has the lowest possible direct current component having. In optical recording it is desirable that the low frequency part of the data spectrum is optimally suppressed, because of the servo controls. It also does demodulation simplified when the direct current component is relatively low

For the above and other reasons, so-called channel coding is applied to the data bits before they are transmitted or recorded via the channel. In the case of block coding (reference material D (I)), the blocks of data bits which each contain m bits are coded as blocks of information bits which each contain nj information bits. In Fig. 1 shows how the block of data bits BDi is converted into a block of information bits BIi . As an example, / 7i = 14 is chosen in the further description and in the figures. Because n \ is greater than m, not all combinations that can be formed with n \ bits are also used; those combinations which do not match the channel to be used are not used. In the example given, therefore, of the 16,000 possible channel words, only 256 words need to be selected for the required one-to-one mapping of data words to channel words. Therefore, at

the channel words some requirements are made. One requirement is that between two consecutive information bits of a first type, type "1", there are at least d immediately consecutive information bits of a second type, type "0", within the same block of n \ information bits. Table I on page 439 of reference D (1) shows how many binary words there are depending on the value of d. The table shows that for n \ = 14 277 words with at least two (d = 2) bits of type "0" between successive bits (of type "1"). When coding blocks of 8 data bits, of which 2 ⁸ = 256 combinations can occur, as blocks of 14 channel bits, the requirement d = 2 can definitely be met.

A together closing of the blocks of information sheet ₁ is not readily possible when the same request for a (/ limitation is placed not only within a block of n \ bits, but calculated over the boundary of two consecutive blocks of time. For this purpose, in the reference material D (I) proposed (page 451) to include one or more separator bits between the blocks of channel bits.It is easy to see that if at least a number of separator bits of type "0" are included, which is equal to d , then the requirement of a (/ -Limitation is fulfilled for the entire sequence of channel bits. FIG. 1 shows that a block of channel bits BQ consists of the block of information bits Bh and a block of separating bits SS. The block of separating bits has /? 2 bits, which means that the Block channel bits BQ has n \ + ni bits As an example, in the further description and in the figures, if not stated otherwise, ni = 3 is chosen.

In order to make the clock pulse generation as reliable as possible, the requirement can also be made that the maximum number of type "0" bits that can occur continuously between two consecutive type "1" bits within only one block of information bits is limited to a certain number Value k is bounded. In the example given with m = 8 and / 7 | = 14, from the 277 words that correspond to condition d = 2 , for example, those words can be eliminated that have a very large value for A:. It turns out that k can be constrained to ten. Therefore, a sequence of 2 ⁸ (generally 2 "') blocks of data bits each of 8 bits (generally m) is mapped onto a sequence of likewise 2 ⁸ (generally 2 ^m ) blocks of information bits, which are also defined by the requirement d = 2 and k = 10 (generally d, it-limited) from 2 ^U (generally 2 "') possible blocks of information bits are selected. The assignment of each of the blocks of data bits to only one of the blocks of information bits is in itself still a free choice. In the cited reference material D (I), the conversion of data bits into information bits is clearly determined in a mathematically closed form. Although this conversion is basically usable, a different assignment is preferred, as will be explained in more detail below.

Linking the also jt-limited channel values Bl, is, as was the case for only (/ -limited blocks, only possible if separating blocks are provided between the blocks of information bits Bl, - . Basically, the same separating blocks of / 72 bits each can be used for this purpose because the requirements (/ -limited and / r-limited) are not contradicting but rather complementary.

If the sum of the number of bit values of type "0" that precedes a certain separator block, the number that follows the separator block, and the / J ₂ bits of the separator block itself should exceed the value k , then at least one of the bit values of type "0" of the separator block must be replaced by a bit value of type "1" so that the sequence of zeros is divided into sequences that are each at most k long.

In addition to ensuring that the requirements of the (d, λ ^ limitation are met, the separating blocks can be dimensioned in such a way that they can also be used to minimize the direct current component Information bits, a certain format of the separator bit block is prescribed, but that in a large number of cases either no requirements or only limited requirements are made of the separator bit block format.The space created in this way is used to minimize the direct current component.

The development and growth of the direct current component can be explained as follows. The block information bits B1] according to FIG. 1b is defined, for example, in the form of an NRZ mark format on the recording medium. In this format, a "1" is held by a transition at the beginning of the relevant bit cell and a "0" is recorded as no transition. The bit sequence, shown in Bl then takes a form that is by and WFbezeichnet in this bit sequence is recorded on the record carrier. This sequence has a direct current component because the length of the positive level exceeds the negative level in the relevant sequence. A measure that is often used for the direct current component is the digital sum value, abbreviated DSW. The DSIV is, provided that the levels of the waveform WF + 1 and - 1, respectively, then equal to the running integral of the waveform IVF and is in the one shown in FIG. 16 shown example + 67 ^ where Γ is the length of only one bit interval. If such successions are repeated, the direct current component will increase. This direct current component generally leads to a base line movement and reduces the effective signal-to-noise ratio and thus the reliability of the detection of the recorded signals.
The block separating bits BSi is used as follows to limit the direct current component. At a certain moment, a block of data bits BDi is offered. This block of data bits BD is converted, for example by means of a table stored in a memory, into a block of information bits Bl . A number of possible blocks containing (n \ + ni) bits of channel bits are then generated.These blocks all contain the same block of information bits (bit cells 1 up to and including 14, Fig. Ib), supplemented by the possible bit combinations of the / 7 ₂ separating bits (bit cells 15, 16 and 17, Fig. Ib). Therefore, in the example of FIG. Ib a sequence of channel bits, consisting of 2 "2 = 8 possible blocks. The following parameters are then determined from each of the possible blocks of channel bits in a basically arbitrary order:

a) determine whether channel bits for the possible block in question, taking into account the previous block Channel bits the (/ limit requirement and the Jt limit requirement do not coincide with the Format of the relevant block contradicts the separator bit;

b) determine which of the DSIVs is channel bits for the relevant possible block.

A first display signal is generated for the possible blocks of channel bits that do not contradict each other in the requirement of the c / limitation and / r limitation. The choice of the coding parameters ensures that such a display signal is generated for at least one of the possible blocks of information bits. Finally, from the possible blocks of channel bits for which a first display signal is generated, for example, the block channel bits is selected which has the smallest DSW in absolute value. A better method, however, is to store the DSW of the previous blocks of channel bits and, from the blocks of channel bits that are to be transmitted next, to consider that block which allows the stored DSW to decrease in absolute value. The word selected in this way is transmitted or recorded.

One advantage of this method is that the separation bits that are already required for other purposes make it easy to use Way can also be used to limit the DC component. Another advantage is that the intervention in the signal to be transmitted is limited to the blocks separating bits and not to the Blocks of information bits (regardless of the polarity of the transmitted or recorded Waveform). The demodulation of the read out recorded signal then only needs to be based on the information bits to acquire. The separation bits can be disregarded.

Some further exemplary embodiments of the method are shown in FIG. 2 shown. F i g. 2a schematically shows the series of blocks of channel bits BQ- \, BQ, BQ + \, ... which contain a predetermined number (n \ + / J ₂ ) bits. The blocks of channel bits contain blocks of information bits of n \ bits each and blocks of separating bits ... ßS, _2, BSi-u BSi, SS / + 1 ... of n ₂ bits each.

In this exemplary embodiment, the direct current component is determined over several blocks at the same time, for example, as also shown in FIG. 2a, via two blocks of channel bits BQ and BQ ₊ u. 1 in the sense that the possible formats of super blocks are generated for each superblock SBC, ie the blocks information bits for block ßC / and block BCi ₊ ) are combined with all the possible combinations with the / 72 separator bits of the block BSi and the block ßS , + i can be formed, supplements. The combination that minimizes the direct current component is then selected from this set. One advantage of this method is that the remaining direct current component has a more uniform character because it is possible to see in advance which intervention is optimal over more than just one block of channel bits. A favorable modification of this method differs in that the superblock SBC ₁ (FIG. 2a) is shifted by only one block of channel bits BQ after the direct current imbalance has been minimized. This means that the block BQ (in Fig. 2a), which forms part of the superblock SBC, is processed and the following superblock SBQ + \ (not shown) the blocks BC _{l +} \ and BQ + 2 (not shown) contains, whereby the above-described minimization of the direct current imbalance is carried out. The block ßC, + i thus forms part of the superblock SBQ and the subsequent block SßC, + i · It is entirely possible that the (temporary) choice for the separating bits in block ßS, ₊ 1 marked in the superblock SBQ of the final choice deviates in the superblock SBQ ₊ 1. Because each block is used several times (twice in this example), the direct current imbalance and thus the noise component is further reduced.

F i g. FIG. 2b shows a further exemplary embodiment where the direct current component is determined over several blocks simultaneously (SBCj) , for example, as shown in FIG. 2b, over four blocks of channel bits BCjW ₃ BCjW, βC / ⁽³⁾ and BCjW. These blocks of channel bits each contain a certain number n \ information bits. The number of separating bits that the blocks of separating bits BSj ¹ A BSjW, BSjW and BSjW contain, but not the same for each block of channel bits. For example, the number of information bits can be 14, and the number of separating bits can be 2 for each of the blocks BSjW, BSjW and BSjW and 6 for block BSjW. The determination of the direct current component takes place in a corresponding manner as for the exemplary embodiment according to FIG. 2a has been described.

One advantage of this procedure - besides the advantages already mentioned, which also apply in this case - is, that the availability of a relatively long block of separating bits enables the possibility of limiting the direct current component In particular, the remaining DC component of a sequence is channel bits, with each Block channel bits has an equal number of, for example 3 bits, greater than the remaining direct current component a sequence of channel bits, the blocks of which have separating bits on average 3 bits, but distributed in 2-2-2-6 bits.

It should be noted that the described time sequences of functions and associated states of the method can be implemented in universal sequential logic circuits, such as commercially available microprocessors with assigned memories and with assigned peripheral devices. A flow chart such an implementation is shown in FIG. 3 shown. About the names of the blocks that have the functions and explaining the states of the method of coding in time series include the following explanatory Texts. In column A is the reference number, in column B the designation of the geometric block and in column C contains the explanatory text for the geometric block in question.

2 BD,

ίο 3 BIi (BD ₁ )

4 j: -

20th

40 45

7 BG: Bh + BS>

8 DSK '=

9 > kLx1

ίο

11 DSW: = Max

12th

DSW + DSV _ac ,

50 13 min / DSW / =

14 SC, ¹

55 15 DSVV.cc: = DSVA ')

16 /: = .1 + 1

60 The digital sum value (DSW) of the preceding blocks of channel bits is given the value zero at the beginning of the process. The first data word BD is given the number / = 0. The process continues with geometric block 2;

The block of data bits of m bits with the number / is selected from a memory. The process continues with geometric block 3;
The block of data bits with the number ι (BD ₁ ) is converted by means of a table stored in the memory into a block of information bits of Πι bits (BI ₁ ); the process continues with geometric block 4.
A parameter j is initialized to a value 0; the parameter / 'is the number of one of the q blocks of channel bits of n \ + j? 2 bits that may be considered for transmission or recording; the process continues with the geometric block S;
The parameter / is increased by 1; the geometric block 6 follows.
When the relevant parameters of all Q possible blocks of channel bits have been determined, the process is continued, which is denoted by the geometric block 13. This is indicated in the geometric block 6 with the connection N. If j <Q , the process is continued which is indicated by the geometrical block 7;

The / possible block channel bits Z? C / is formed in that the block information bits BI-, with the j. Combination of the block separating bit BSi is added; the geometric block 8 follows;

The DSVdes /. possible blocks channel bits is determined; it will continue with the geometric block 9;

It is tested whether the / 'possible block channel bits when connected to the previous block channel bits BQ- \ fulfills the requirement of the jt limitation.If this requirement is fulfilled, the process specified by the geometric block 10 is continued (connection N). If this requirement is not met, the process is continued, which is indicated by the geometric block 11 (connection Y).

It is tested whether the / 'possible block channel bits when connected to the previous block channel bits BQ- \ fulfills the requirement of the {/ -limitation. If this requirement is met, the process is continued, which is indicated by the geometric block 12 (connection N). If this requirement is not met, the process that is indicated by the geometric block 11 is continued (connection Y);

Such a high value (Max) is assigned to the DSIV of the / 'block channel bits granted that this block can definitely not be selected; the geometric block 12 follows;

The DSlV of /. Blocks channel bits (DSWu)) is added to the stored DSW (DSWacc) of the previous blocks channel bits to obtain a new stored value of the DSW (DSWiH); the geometric block 5 follows;

The minimum value of the DSW of the q possible blocks of channel bits is determined; it turns out that this is the DSW of the 1st block channel bits. The process continues with the geometric block 14;
The 1st block channel bits is selected from the q possible blocks; the process continues with the geometric block 15;
The stored value of the DSW (DSW _act ) is made equal to the stored value of the DSW of the selected 1st block of information bits; the geometric block 16 follows;

The number of the blocks of data and information bits is increased by 1. The process continues with geometric block 2; the cycle is now run through again for the following, den (i + 1). Block data

The above flowchart applies to the embodiment of FIG. 1 applied. For the embodiment according to FIG. 2 apply, taking into account the changes already described corresponding flow charts.

In order to be able to distinguish between the information bits and the separating bits when demodulating the transmitted or recorded stream of channel bits, blocks (773 + nt) synchronization bits are included in the stream of channel bits, namely ni synchronization information bits and nn synchronization bits.

station separation bits. For example, a block of synchronization bits is always inserted after a certain number of blocks of information and separating bits. After this word has been detected, it can then be clearly determined at which bit positions information bits and at which bit positions there are separating bits. It must therefore be avoided that the synchronization word can be imitated by certain bit sequences in the information and separating blocks. For this purpose, for example, a unique block of synchronization bits, ie not appearing in information and separating bit sequences, can be selected. Consequences that do not meet the requirement of the d limitation or it limitation are of less interest because the information density or the self-clocking properties are then impaired. However, within the set of sequences that meet the requirements of the (d, λ / limitation, the choice is very limited.

A different way is therefore suggested. The block of synchronization bits has, for example, at least twice in direct succession a sequence which has s bits of type “0” between two consecutive bits of type “1”. Preferably, 5 is equal to k. A block of synchronization bits SYN is indicated in FIG. The block contains a sequence 10000000000 (a 1 followed by 10 zeros), which is denoted by 5VTVPi or 5VTVP ₂ , twice in immediate succession. This sequence can also occur in the stream of channel bits, specifically for sequences with k = 10 Separation bits and the number of immediately consecutive information bits of type "0" which immediately precede a bit of type "1", which last-mentioned bit forms part of the separator bits block, is equal to k and also equal to the sum of the number of immediately consecutive information bits of the Type "0" that follow the named bit of type "1" of the block of separating bits is the same. The other way already indicated would be to use a sequence 100000000000 (a 1 followed by 11 zeros) twice. The block of synchronization bits also has a block of synchronization separation bits. The function of the block separating bits corresponds to the above-described function of the block of separating bits between the blocks of information bits. (Therefore, they are used to meet the requirements of the (d, k) limitation and the restricted DC component). The measures which have been taken to avoid that the synchronization pattern is mimicked in the sequence of channel bits by occurring twice in immediate succession also prevent this pattern from occurring three times before or after the block of synchronization bits.

The method described above, which is also referred to as modulating or coding, is greatly simplified in the opposite direction, that is to say during demodulation or decoding. The limitation of the DC component has been reached of information without interfering with the blocks, so that the information for demodulating is irrelevant in the separation blocks Furthermore, the choice is made modulator side which m bits long block data bits which n \ bits long block is assigned to information bits, important not only for the modulator but also for the demodulator. The complexity of the demodulator depends on this choice. In magnetic recording systems, the complexity of the modulator and the demodulator are of equal concern because both are generally present in the device. In systems for optical recording, the recording medium is of the "read-only" type ("fixed value"), as a result of which the consumer device only needs to receive a demodulator. In the latter case, it is particularly important to minimize the intricacy of the demodulator, even at the expense of the intricacy of the modulator.

In Fig. 5 shows an exemplary embodiment of a demodulator which demodulates the blocks of 8 data bits from blocks of 14 information bits. F i g. 5a shows the block diagram of the demodulator and FIG. 5b schematically shows part of the wiring. The demodulator contains AND gates 17-0 up to and including 17-51, each with one or more inputs. One of the 14 bits of the blocks of information bits is fed to each of the inputs, which may be designed to be inverted. In FIG. 5b, column C indicates how this is designed. Column 1 represents the least significant bit position Q of the 14-bit information block, column 14 the most significant bit position CW and the intermediate columns 2 to 13 inclusive represent the other significant bit positions corresponding to their position. Lines 0 to 51 relate to the ranking of the UN D gate, ie line 0 relates to the input format of AND gate 17-0, line 1 relates to the input format of AND gate 17-1, etc. A character 1 in the ^ column Line./ means that the / AND gate 17 at a non-inverting input contains the content of the /. Bit position ß, is offered. A character 0 in the /. Column on line j means that the / AND gate 17 is offered the content of the L bit position (C ₁ ) at an inverting input. Therefore (line 0) an inverting input of the AND gate 17-0 is connected to the 1st bit position (C \) and a non-inverting input is connected to the 4th bit position (Q) ; furthermore (line 1) a non-inverting input of the AND gate 17-0 is connected to the 3rd bit position (C3) etc.

The demodulator also contains 8 OR gates 18-1 up to and including 18-8, the inputs of which are connected to the outputs of the AND gates 17-0 up to and including 17-51. In FIG. 5b, under column A, it is indicated how this is achieved. The column A \ relates to the AND gate 18-1, the column Ai relates to the AND gate 18-2 ... and the column A ₈ relates to the AND gate 18-8. A letter A in the i. Column of the / row indicates that the output of the AND gate 17- / is connected to the input of the OR gate 18- / '.

The connection for AND gates 17-50 and 17-51 has been changed as follows. An inverting output of the AND gates 17-50 and 17-51 are each connected to an input of a further AND gate 19. An exit the OR circuit 18-4 is connected to a further input of the AND gate 19.

The outputs of the OR gates 18-1, 18-2, 18-3 and 18-5 up to and including 18-8 and an output of the AND gate 19 are each connected to an output 20- /. The decoded output is therefore in parallel at this output Block of 8 data bits available.

The demodulator according to FIG. 5a can also be implemented by means of a so-called FPLA (»field programmable logic

array «), for example, the Signetics bipolar FPLA of type 82S100 / 82S101. The table according to FIG. 5b forms the programming table for this.

The demodulator according to Fig.5 is due to its simplicity for systems for optical recording from "Read-only" type quite suitable

The block of synchronization bits can be detected by means which are shown in FIG. 6 are shown. The transmitted or read out recorded signal is fed to an input terminal 21. The signal is in the NRZ-M (ark) format. This signal is fed directly to a first input of an OR gate 22 and via a delay element 23 to a second input of the OR gate 22. At the output of the OR gate 22, which is connected to the input of a shift register 24, there is a so-called NRZ -I signal available. The shift register contains parts with one tap each, the number of which corresponds to the number of bits that the block of synchronization bits has. In the example already used above, the shift register must have 23 parts in order to be able to contain the sequence 10000000000100000000001. Each tap is connected to an optionally inverting input of an AND gate 25. If the synchronization sequence is present at the inputs of the AND gate 25, a signal is generated at an output 26 of this AND gate which can serve as a display signal for detecting the synchronization pattern. With the help of this signal, the stream of bits is divided into blocks of (m + m) bits. These blocks of channel bits are shifted one after the other into another shift register. The most significant m bits are read out in parallel and fed to the inputs of the AND gates 17 as indicated in FIG. 5a. The least significant n ₂ bits are irrelevant for demodulation

The coded signal is recorded, for example, on an optical recording medium. The signal has a form given by WF in Fig. Ib. On the record carrier, the signal is applied in a spiral information structure. 7 is shown. A superblock SBi contains a block of synchronization bits SYNj as in FIG. 4 and a number (33 in the exemplary embodiment) blocks of channel bits each of (tt \ + m) bits BQ, BC ₂ ... BCn. A channel bit of type "1" is represented by a transition in the record carrier, for example a transition to a pit; a channel bit of the type "0" is represented on the record carrier by the absence of a transition. The spiral information track is divided into elementary cells, the bit cells. These bit cells form a spatial structure on the recording medium which corresponds to a division in time (period time of only one bit) of the stream of channel bits.

Regardless of the content of the information and separating bits, a number of special features can be recognized on the recording medium. The requirement of the Ar limitation means for the carrier that the maximum distance between two successive transitions is k + 1 bit cells. The longest course (or non-deepening) thus has a length of (k + 1) bit cells. The requirement of the «/ limit

means that the minimum distance between two successive transitions is d + 1. The shortest indentation (or part between two indentations) therefore has a length of (d + 1) bit cells. Furthermore, a depression with the maximum length occurs at regular intervals with a subsequent (or preceding) non-depressed part with the maximum length. This structure forms part of the block of the synchronization bit.

In a preferred embodiment? is Ar = 10, d = 2 and contains a superblock SS; 588 channel bit cells. The superblock SS contains a block of synchronization bits of 27 bit positions and 33 blocks of channel bit cells of 17 (14 + 3) channel bit cells each.

A modulator, a transmission channel, for example an optical recording medium and a demodulator can together form part of a system, for example a system for converting analog information (music, speech) into digital information that is recorded on an optical recording medium. The information recorded on this recording medium (or a copy thereof) can be reproduced by using an arrangement which is suitable for reproducing the type of information which is fixed on the recording medium.
The converter contains in particular an analog-to-digital converter for converting the analog signal to be recorded (music, speech) into a digital signal of a specific format (source coding). Furthermore, the converter can contain part of an error correction system. In the converter, the digital signal is converted into a format with which the errors which occur in particular when reading out the recording medium can be corrected in the arrangement for reproducing the signals.

The digital error-protected signal is then sent to the modulator described above (channel coding) for conversion into a digital signal adapted to the channel properties. At the same time it will Synchronization pattern is supplied, and the signal is brought into a suitable frame format. That on this A signal obtained in this way is used to generate a control signal, for example for a laser (NRZ-Mark format), with which a spiral information structure in the form of a series of indentations Lengths is attached to the recording medium.

The recording medium or a copy of it may have been an arrangement for reproducing the Aufzcichni_inCTQtrsicy the _r £ taken! Nforniäiioniibits üus ^a clcscn. The Anordnun * ⁷ contains a demodulator düKU already described in detail, the decoder part of the Fehlerkorrektursystcnis and a digital-analog converter for recovering a representation of the analog signal which is presented to the transducer.

In addition 5 sheets of drawings

Claims (15)

Patent claims: 1. Method for recoding a sequence of data bits into a sequence of channel bits, the sequence of data bits being divided into consecutive blocks of m data bits each and these blocks into consecutive blocks of (m + n ₂ ) channel bits (n \ + n ₂ > / n ^ are recoded and the blocks of channel bits each contain a block of n \ information bits and a block of n ₂ separating bits in such a way that successive blocks of information bits are separated by only one block of separating bits each, and that a (W, k) condition is met , ie that two consecutive channel bits of a first type, of type "1", are separated by at least c / then at most k consecutive bits of a second type, of type "0", ίο, characterized by the following steps: -1- converting the blocks of data bits containing m bits into blocks containing n \ bits of information bits such that the (d, Jr ^ condition is met; -2- the generation of several possible blocks of (n \ + n ₂ ) channel bits by adding one block of n \ information bits each with one block from the set of all possible blocks of n ₂ separating bits; -3- the determination of those blocks of channel bits from the possible blocks of channel bits which meet the (i.e. J ^ condition with respect to the respective preceding and following block of channel bits; -4- the determination of the equal fraction of each of the blocks of channel bits determined in this way, which are in the preceding Step were determined; -5- the selection of the block of channel bits with a minimum DC component from those determined in step 4 Blocks. 2. The method according to claim 1, characterized in that the third step further includes the following Sub-step has: -3a- the suppression of those blocks of channel bits for which the number of immediately consecutive channel bits of type "0" determined in the third step, which immediately precedes a bit of type "1" of the separator bit block, is also the same as in the in the third step, the number of immediately consecutive channel bits of the type “0”, which immediately follows a bit of the type “1” of the block separating bits, and is equal to a predetermined number s ; and that the method further comprises the following steps: -6- arranging a number of blocks of (n _t + n ₂ ) channel bits in immediately successive frames of ρ blocks each; -7- the insertion of a block of synchronization channel bits between two consecutive frames, the block of synchronization channel bits having a specific block of n ₃ synchronization information bits and this block at least twice in direct succession between two consecutive bits of the type »1« s bits of the type »0 «And furthermore has a block of / J4 synchronization separation bits, which is determined by carrying out steps -2- through -5- in relation to the synchronization channel bits block. 3. The method according to claim 2, characterized in that s = k . 4. The method according to any one of the preceding claims, characterized in that the fifth shrill furthermore has the following substeps: The determination of the stored direct current component of the preceding blocks of channel bits; - Determining the absolute value of the sum of the stored direct current component and the direct current component each of the blocks of channel bits determined in the third step. 5. The method according to any one of the preceding claims, characterized in that four blocks of information bits each of /? I bits and four blocks of separating bits alternately follow one another, of which three blocks of separating bits have a first length n ₂ and one block has a length n ₂ " has with n ₂ "> n ₂ . 6. Procedure according to. Claim 5, characterized in that /? Ι = 14, nj = 2, n ₂ "= 6 and m = 8. 7. The method according to any one of claims 1 to 4, characterized in that in each case a block of information bits of n \ bits and a block of separating bits of n ₂ bits follow one another. 8. The method according to claim 7, characterized in that / 7 | = 14, n ₂ = 3, and / n = 8. 9. Demodulator for decoding the according to the method according to any one of claims 2 to 8 recoded Kanalbiis, characterized by - Means / to Detpktierpn the .Synchmnisatinnsmiisler: - Means for dividing the sequence of channel bits into blocks of (n \ + n ₂ ) channel bits each; - means for separating the blocks of n \ information bits from the blocks of n ₂ separating bits; - Means for converting a block of n \ information bits into a block of m data bits. 10. Demodulator according to claim 9, characterized in that the means for converting AND Torc, the inputs of which the information bits from at least one specific bit position of the block of information bits are fed in parallel, and have OR gates whose inputs are connected to the outputs of the AND gates are connected and their outputs deliver the decoded m data bits in parallel. 11. Record carrier with an information structure generated according to the method according to one of claims 1 to 8 with sequences of channel bit cells each containing a bit whose value is represented by a level transition or a missing level transition at the beginning of the bit cell, characterized in that the distance between two consecutive level transitions is at most equal to (k + 1) bit cells and minimally equal to (d + 1) bit cells and that at most two consecutive maximum distances of (k + 1) bit cells of the level transitions occur which form part of synchronization information. 12 Record carrier according to Claim 11, characterized in that k = 10 and d = 2 and that the record carrier between two successive synchronization information items has a frame with 56 * channel bit cells which contains 33 blocks of 17 channel bit cells each, and that the synchronization information item includes 27 channel bit cells 13. Modulator for recoding a sequence of data bits into a sequence of channel bits according to the method of FIG one of claims 1 to 8. 14. Converter for converting an analog signal to be recorded into the sequence of channel bits with a modulator according to claim 13. 15. Arrangement for reproducing the one transmission channel, in particular a recording medium, extracted information bits with a demodulator according to claim 9 or 10.