SE456708B - PROCEDURES CODE A SEQUENCE OF BLOCK OF BINARY CHANNEL BITS, DEMODULATOR FOR DECODING THE DATA BITES CODED IN ACCORDANCE WITH THE PROCEDURE, AND A RECORDING MEDIUM WITH AN INFORMATION STRUCTURE SUCH AS A CONTENT - Google Patents

Description

456 708 synchronization sequence, this would destroy the synchronization signal. clarity and, consequently, its suitability for that purpose. It can further the transitions are not required to follow each other too closely to the ball interference shall be limited. C In the case of magnetic or optical recording, this requirement may also be related to the information density of the recording medium because, if, at a predetermined minimum distance between two consecutive transitions on the recording diet, the corresponding minimum time interval (Tmin) of the signal as to be recorded increases, the information density increases to the same degree. Even the experienced min) is correlated to the minimum distance Tmin between transitions (Bmin = 1 / 2Tmín).

If you use information channels that do not transmit direct current, such as is the case with magnetic recording channels, this results in the requirement that the symbol sequences in the information channel shall contain the lowest possible (even minimum bandwidth (B virtually no) DC component.

MÅL Kë fl âíßí * í fl lß - A process of the kind initially described is discussed in reference D (1). The article refers to block codes based on d-, k- or (d, k) -limited q-close blocks of symbols, which blocks meet the following conditions: (a) d-restriction: two "1" type symbols are separated by a sequence of at least d consecutive symbols of "O" type; (b) k-constraint: the maximum length of a sequence of consecutive symbols of ty- pen "D" is k.

A sequence of e.g. binary data bits are divided into consecutive and sequential tial blocks with each m data bits. These blocks with m data bits are coded to blocks of n information bits (n> m). Since n> m exceeds the number of tion with n information bits the number of possible blocks of data bits (2m). If for example The d restriction requirement is applied to the blocks of pieces of information, which shall transmitted or recorded, a transformation (mapping) of the Zm is selected blocks of data bits to likewise 2m blocks of information bits (of one possible number of 2 "blocks) so that transformation is only performed on the blocks of pieces of information that meet the set requirement.

Table I on page 439 of reference D (1) shows how many different blocks of formation pieces there are depending on the length of the block (s) and the requirement is set to d. There are thus eight blocks of information pieces with a length n = 4 provided that the minimum distance d = 1. Consequently, blocks of data with a length m = 3 (23 = 8 data words) is represented by blocks of information 456 708 bits with a length n = 4, whereby two consecutive symbols of the "1" type in the blocks of information bits are separated by at least one "0" type symbol. IN this example becomes the coding where (<& -?) indicates transformation of a block to the second block and vice versa): ooo <--> oooo ' 001 <"'__> 0001 010 <: "" ° '0010 011 <--> o1oo 100 <* ”'fi> 0101 101 <= - fi> 1000 110 1001 111 <2- ~> 1010 When setting up the block of information pieces, however, it is in some case it is not possible to satisfy the requirement (in the example d-condition) without take further action. In the said article it is proposed to include separate ration bits between the blocks of information bits. In the case of the d-condition code is a block of separation bits comprising d-bits of type "0" enough. In the above example where d = 1 is therefore a separation bit (a zero) enough. Each block with three island pieces is then coded by 5 (4 + 1) channel pieces.

This coding method has the disadvantage of the contribution of low frequencies (extensive direct current) to the frequency spectrum of the current of channel bits becomes relatively high. Another disadvantage is that the coding converters (modulator, demodu- lator), in particular the demodulator, become complicated.

With regard to the first disadvantage, it is observed that the reference D (2) indicates that the direct current imbalance of (d, k) - condition codes can be limited by interconnecting ling of the blocks of channel pieces by means of a so-called inverting or non-inverting they link. When you do, the character of the contribution is selected from the current block pieces of cinnamon to the direct current imbalance so that the direct current imbalance of the only blocks of channel bits are reduced. However, this refers to a (d, k) - error cross code, whose blocks of information bits can be linked up without getting 1 con- duty with (d, k) - the condition, so that the addition of separation bits of (d, k) - conditional reasons are not necessary.

(B) Summary of the Invention.

An object of the invention is to provide a method of initiating described type for encoding a sequence of binary data bits into a sequence of binary channel bits, which method improves the low frequency spectrum 456 7os the characteristics of the signal derived from the channel bits, and the procedure they enable the use of a simple demodulator. _ The method according to the invention is characterized in that it comprises the following jande rose. Conversion of blocks containing m-bits of data bits to blocks containing n bits of pieces of information, Generation of a group of possible sequences of channel bits, each sequence comprises at least one block of information bits and one block of separate pieces, these possible sequences each comprising the blocks of formation bits supplemented by one of the possible bit combinations for block separation pieces; Determination of the DC imbalance of each of the possible sequences of channel bits determined in the previous step, Determination for each of the possible sequences of channel bits sum of the number of separation bits and the number of consecutive and sequential "0" type bits immediately preceding a "1" type bit and the sum of the number following a "1" type bit, which bit forms part of one of blocks of separation pieces, as well as the sum of the number of separation pieces and consecutive and sequential pieces of information of the "0" type as immediately precedes and follows this block of separation pieces, . Generation of a first indication signal for the sequences of channel bits for which the values of the sum determined in the previous step are higher than 2 d but not more than = k. 6. Selection from the sequences of channel bits, which resulted in the first the indication signal, of the sequence of channel bits which minimizes direct current lance.

C. Summary of the drawings.

Embodiments of the invention and their advantages will now be described with reference to the drawings, where fjg_l shows some bit sequences for illustrate an embodiment of the coding format according to the invention, sar some other embodiments of the format of the channel coding used in the reduction of the direct current imbalance according to the invention, _fig_§ shows a flow diagram of an embodiment of the method according to the invention, fig. a block of synchronization bits for use in the method according to invention, shows an embodiment of a modulator in accordance with the invention. the invention for decoding data bits, which are encoded in accordance with the method, Fig. 1 shows an embodiment of means for detecting a sequence of chronization bits according to the invention and jjg_Z show an embodiment of a frame format intended for use in the method according to the invention. 456 708 Threatening elements have been provided with the same reference numerals in the different figures. Égfišfíå fi äflššf '' (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, pp. 436-461. (2) Patel, A.M., "Charge-constrained byte-oriented (0.3) code", IBM Technical Disclosure Bulletin, Vol. 19, no. Dec. 7 1976, pp. 2715-2717.

E. Description of the embodiments.

Fig. 1 shows some bit sequences to illustrate the encoding method of a stream of binary data bits (Fig. 1a) to a stream of binary channel bits (Fig. 1b). The stream of data bits is divided into consecutive and sequential blocks BD. Each block of data bits includes m data bits. As an example, the choice m = 8 to be used in the following description and in the figures. The same applies however, for any other value of m. A block of m data bits BDi includes generally takes one of Zm's possible bit sequences.

Such bit sequences are not so suitable for direct optical or magnetic record and this for several reasons. Namely, if two data symbols of type "1", which e.g. recorded on the recording medium as a transition from a magnetic direction to the other or as a transition to a pit, follows immediately after each other, these transitions must not be too close to each other given their mutual interaction. This limits the density of information.

At the same time, the minimum bandwidth Bmin required to transmit or increase draw the bitstream, if the minimum distance Tmín between consecutive transitions (Bmin = 1 / Zïmínl is small. Another requirement, which often applies to data transmission and optical or magnetic recording systems, is that the bit sequence must have sufficient transitions to from the transmitted signal it must be possible to recover a clock signal with which synchronization can be performed.

A block down with zeros which in the worst case is preceded by a block, which ends with a number of zeros and is followed by a block, starting with a number of zeros would jeopardize the clock signal generation.

Non-direct current information channels, such as magnetic recording must also meet the requirement that the data stream to be recorded includes a DC component that is as small as possible. At optical recording, it is desirable that the low frequency portion of the data spectrum be depressed as far as possible with a view to the power steering.

In addition, demodulation is simplified if the DC component is relatively ten. 456 708 For the above-mentioned and for other reasons, a so-called channel coding on data the bits before they are transmitted via the channel or before they are recorded. In the fall with block coding (reference D (ll) the blocks are coded by data bits, as each given contains m bits, such as blocks of information bits, each of which includes tar nl information pieces. Fig. 1 shows how the block of data bits BDi is converted read to a block of pieces of information Bli. As an example, the choice was used n1 = 14 in the following description and in the figures. Then nl is greater than m not all combinations that can be formed with nl bits are used: The combinations ions that do not fit well with the channel used were not used. In the example thus, only 256 words need to be selected from the more than 16,000 possible channel words for the required one-to-one transformation of data words into channel words.

Consequently, certain requirements can be placed on the channel words. One requirement is that between two consecutive pieces of information of a first type, type "1", at least d sequential and consecutive pieces of information of a type, type "0", are located within the same block with nl pieces of information. Table I on page 439 of reference D (1) shows how many such binary words there are depending on the value of d the table that for nl = 14 there are 277 words with at least two (d = 2) bits of type "0" between consecutive bits (of type "l"). When coding blocks with 8 data bits of which there may be 28 = 256 combinations, as blocks of 14 channel pieces, the requirement d = 2 can therefore be easily satisfied.

However, compiling the blocks of information bits Bli is not possible without further action, if the same requirement of d-conditions does not only apply within a block of nl bits but also extends across the boundary between two consecutive blocks. For this purpose, reference D (1) (page 451) suggests that insert one or more separation bits between the blocks of channel bits. It is easy to see that if a number of separation bits of type "0", which are at least equal with d, the d condition is introduced and is met. Fig. 1 shows that a block of channel BCí consists of the block of information bits BI¿ and a block of separate tionsbitar BSi. The eloquence of separation pieces includes na pieces so that the block of channel bits BC¿ comprises nl + nz bits. As an example comes the choice n2g = 3 to be used in the following description and in the figures unless otherwise stated.

In order to make the clock generation as reliable as possible, an more demanding requirements be that the maximum number of bits of type "0", which can occur without interruption between two consecutive bits of type "1" within a block of information bits, is limited to a predetermined value k. In the example where m = 8 and nl = 14 it is e.g. possible that of the 277 words that meet the requirement d = 2 eliminate the words, which have a very high value of k. It appears that k can - 456 708 be limited to 10. Consequently, a group of 28 (generally) is transformed Zm) blocks of data bits with 8 bits each (generally m) to a group that also comprises 28 (generally 2m) blocks of pieces of information, which bits have been selected from 214 (generally 2 "1) possible blocks of information which is partly the result of the fact that the following requirements have set: d = 2 and k = 10 (generally d, k-condition). You are still free to select which block of the blocks of data bits to assign to one of the blocks of pieces of information. In the mentioned reference (D1) a translation from data bits to information bits unambiguously determined in a mathematically closed form. Although this translation can in principle be used, preference is given to another association, as explained below.

Composition of the additional k-constrained channel words BIi is only possible, which also applies to the d-conditional blocks, if the separation blocks has been arranged between the blocks of information bits Bli. In principle, the same can separation blocks of n2 bits each are used for this purpose when the requirements of d-conditions and k-conditions do not contradict each other but are quite complex. mental. Thus, if the sum of the number of bit values of type "0", which precedes one given separation block, _the number of values following this separation exceeds ration block and the nz bits in the separation block itself exceed the value k, at least one of the bit values of type "0" in the separation block shall be is set with a bit value of type "1" to break the sequence of zeros to sequences, each of which is not more than k bits long.

In addition to their function to ensure that the requirements of (d, k) conditions are fulfilled, the separation blocks can be dimensioned so that they can also be used to minimize direct current imbalance. This is based on the insight of the fact that for some compilations of blocks of pieces of information one predetermined format on the block of separation pieces is prescribed, but that in in a large number of cases either no requirements or only limited requirements are set on the formate of the block of separation pieces. The degree thus obtained of freedom was used to minimize current imbalance.

The emergence of the direct current imbalance and its growth can be explained by way. The block of information bits B11 shown in Fig. 1b is recorded. on the recording medium, e.g. in the form of an NRZ marking format. At this a "1" is marked by a transition at the beginning of the current bit cell ch becomes "0" when no transition is recorded. The bit sequence shown at B11 then assumes a form denoted by WF, in which form this bit sequence is drawn on the recording medium. This sequence then has a direct current imbalance in it the present sequence the positive level has a length which is greater than it 456 708 s negative level. One measure that is often used for direct current imbalance is the digital speak the sum value, abbreviated to d.s.v. Assuming the curve shape levels are NF + 1 and - 1, respectively, becomes the value of i.e. thereby equal to the current integral of the waveform NF and is + 6 T in the example shown in Fig. 1, where T is it at a bit interval. When such sequences are repeated, the direct current imbalance occurs to grow. In general, this DC imbalance results in a baseline shift which reduces the effective signal-to-noise ratio and consequently reliability in the detection of the recorded signals.

The block of separation bits BSi is used in the following manner to determine limit direct current imbalance. At a given time, a block of data is added tar Bßi. This block of data bits BDi is converted into a block of information tionsbitar B1í, e.g. by means of a table stored in a memory. Then generates a group of possible blocks of channel bits containing lnlfnz) pieces. All these blocks comprise the same block of information bits (bit cell 1 to 14 in Fig. 1b) supplemented by the possible bit combinations of the ng the separation bits (bit cells 15, 16 and 17 in Fig. 1b). In that in Fig. 1b shown example, a group consisting of 2 "/ 2 = 8 possible is consequently generated blocks of channel pieces. Then the following parameters are determined from each of the possible blocks of channel pieces, in principle in an arbitrary sequence: (a) it is determined for the current possible block of channel pieces with regard to to the previous block of channel bits, if the d-condition requirement and the k-condition the requirement does not conflict with the format of the present block of separation tionsbitar: b) determination of the value of d.s.v. for the current, possible block of channel pieces.

A first indication signal is generated for the possible blocks of channel bits which is not in conflict with the d-condition requirement and the k-condition requirement. The choice of code the parameters guarantee that such an indication signal is generated for at least one of the possible blocks of information pieces. Of the possible blocks of channel bits for which a first indication signal has been generated is selected for example finally the block of channel pieces which in the absolute sense has the lowest the value of d.s.v. But an even better method is the accumulation of the value of d.s.v. for the previous blocks of channel bits and that among the blocks of channel bits, which are conceivable for the next transmission, the block is selected which will bring the absolute value of the accumulated value of i.e. to reduce. The word thus selected is transmitted or recorded.

An advantage of this method is that the separation pieces, which are already necessary for other purposes, can now also be used in a simple way for limiting 456 '708 direct current imbalance. An additional advantage is the influence on the signal to be transmitted is limited to the blocks of separation bits and stretches not to the blocks of pieces of information (if one disregards the polarity of the waveform transmitted or recorded). The demodulation of the recorded the signal after reading is then only related to the information bit na. The separation pieces can be left without consideration.

Fig. 2 shows some further embodiments of the method. Fig. 2a shows schematically the sequences of blocks of channel bits ....., BCi_1, BC¿, BCi + 1, ... ....., which blocks comprise a predetermined number of (n1 + n2) bits.

Each block of channel bits includes blocks of information bits consisting of nl bits and blocks of separation bits ...... BSi_1, BSi, BSi + 1, ....., each consisting of nz pieces.

In this embodiment, the direct current imbalance is determined over several blocks, e.g. as shown in Fig. Za over two blocks of channel bits BCi and BCi + 1. Like- the current imbalance is determined in a similar way to that described for guide form in Fig. 1 provided that the possible formations of superblocks generated for each superblock SBCi, i.e. blocks of pieces of information for block BC¿ and block BCi + 1 are supplemented with all the possible combinations, which can be formed with the n2 separation bits in block BSi and block BSi + 1.

The combination that minimizes direct current imbalance is then selected from this group. This method has the advantage of the remaining DC imbalance has a more even character as it will refer to more than one block of channel pieces that do intervened optimally.

An advantageous variant of this method is characterized in that the super- block SBCi (Fig. Za), a block of channel bits is shifted since the DC imbalance then has been minimized. This means that block BCí (in Fig. 2a) which is a part of the superblock SBCi is processed and that the subsequent superblock SBCi + 1 (not shown) contains the blocks BCi + 1 and BC¿ + 2 (not shown) for which it the DC imbalance minimization operation described above is performed. Thus is block BC¿ + 1 part of both the superblock SBC¿ and the subsequent one block SBC¿ + 1. It is then quite possible that the (provisional) choice for the separation bits in the block BS¿ + 1 made in the superblock SBCi differ from the final selection made in the superblock SBC¿ + 1. Then each block determined several times (twice in the present example) is reduced the current imbalance and consequently the disturbance contribution further.

Fig. Zb shows another embodiment in which the direct current imbalance is determined for several blocks simultaneously (SBCJ), e.g. as shown in Fig. 2b for four blocks of channel bits BCj (l); BCj (2), BCj (3) and BCj (4). Each of these 456 708? M blocks of channel bits comprise a predetermined number of nl information bits tar. The number of separation bits present in the blocks of separation bits BSj (1), However, BSj (2), BSj (3) and BSj (4) are not the same for each block of channel pieces. The number of pieces of information can e.g. amount to fourteen while the Separation hits for blocks BSj (1), BSj (2) and BSj (3) can be two for each block and six for blocks BSj (4). Determination of direct current imbalance performed in a manner similar to that described for the embodiment according to fig Za.

In addition to the already mentioned advantages, which also apply here, it has method has the advantage that the availability of a relatively long block of bits increase the possibilities of reducing the direct current imbalance. More particularly is the remaining DC imbalance of a sequence of channel bits, in which each block of channel pieces comprises an equal number of e.g. three pieces greater than the remaining DC imbalance of a sequence of channel bits, whose blocks of separation bits comprise an average of three bits but divided into 2-2-2-6 bits.

It is observed that the described time sequences of functions and associated state in the process can be realized by universal sequencing logical logic circuits, such as commercially available microprocessors with associated memories and peripherals. Fig. 3 shows a flow chart for a such realization. The following explanatory text refers to the terms in the the geometric figures, which time-sequentially illustrate the functions and the conditions of the coding method. Column A shows the reference symbol, B shows the designation and column C the explanatory text assigned to the current one geometric figure.

A B C 1 DSC: = 0; i: = 0; The digital sum value (i.e.) for the previous blocks of channel bits are given value zero at the beginning of the procedure.

The first data word BD is given the number i = 0.

Go to geometric figure 2; 2 Bßi The block of data bits with m bits with the number in is selected from a memory.

Proceed to geometric figure 3; 7 8 Bli (Boi) J = j + 1 j._ J BCi.-BIi + BS _ osv5 =? 456 708 11 Biocket of data pieces with taiet in (BD¿) converted to a block of pieces of information consisting of nl pieces (Bli) medeïst one table stored in memorygcontinue tiïi geometric figure 4; A parameter j is initialized at a value 0; parameter j is taiet for one of the q biocken of kanai bits, which consist of n1 + n2 bits and which eventueiit are conceivable for transmission eiier record; proceed to the geometric figure ; The parameter j is increased by 1; continue to geometric figure 6.

Then the actual parameters have been determined for aiia q possible bïock of kanaibitar continues through the operation, indicated by the geometric figure 13. In the geometric figure 6 this is indicated by the notch N. If j-5 Q continues through the operation specified through the geometric figure 7; It jze possible biocket of kanaibitar BC¿ is offered by competing for the foundations Bïí with the jze combination the biocket of separation pieces B53; proceed to geometric figure 8; The value i.e. for the jze möjiiga bïocket of kana1bits are determined; Continue to the geometric trical figure 9; ll 12 456 7Û8 J > 1 kmax ' <dijl? -1 DSV (j): = max (J) ._ etc. acc.- (eel nsv + osvacc 12 The possible block is being investigated of channel pieces when assembled with the going bldcken of channel pieces BCí_1 satisfies k- the conditional requirement. If this requirement is met, it will continue the process through the operation specified in it geometric figure 10 (linkN). About these requirements is not fulfilled, the subsequent step is the ration, which is indicated by the geometric fi- guren 11 (link Y).

It is investigated whether the j: e possible the block of channel pieces when assembled with it the previous block of channel bits BCi_1 satisfies d-condition requirement. If this requirement is met is the next step is the operation that is indicated by the geometric figure 12 (link N).

If this requirement is not met, the the race through the step indicated by it geometric figure 11 (link Y); The value of d.s.v. for the jze block of channel pieces are given such a high value (max) that this block can definitely not be chosen; proceed to the geometric Fig. 12; The value of i.e., for the jze block of channel bits (DS (j) are added to it accumulated the value of dsv (DSVÖCC) for the previous blocks of channel bits to obtain a new accumulated value of i.e.

DSV (ggc; continue to geometric Figure 5; 456 708 13 13 mfnq / osvwosvfe): the minimum value of asv for the q possible the blocks of channel pieces are determined. ßetta turns out to be the value of d.s.v. for the first block of channel pieces (proceed to geometric fig.14); 14 BC! The first block of channel pieces selected from the q possible blocks; proceed to geometric fig.15; DSVacc: = DSV (1) The accumulated value of d.s.v.

(DSV) is made equal to the accumulative acc the value of d.s.v. for the chosen first block of pieces of information; proceed to geometric fig.16; 16 i: = i + l The number of blocks of data and information bits are increased by one. Continue to geometric figure 2; The cycle is repeated now for the next block, the (i + 1) 1st block of data bits.

The flow chart shown applies to the embodiment shown in Fig. 1.

For the embodiments according to Fig. 2, the corresponding flow diagrams with regard to of the modifications already described.

In order to demodulate the transmitted or recorded current of channel bits enable a distinction between the information bits and the bits (n3 + n4) bits are inserted, namely n3 synchronization information bits takes and n4 synchronization separation bits, in the channel bit block stream. One block of synchronization bits are introduced e.g. each time after a predetermined number blocks of information and separation pieces. After detecting this synchronous words, one can then unambiguously determine in which bit positions there is information information bits and in which bit positions there are separation bits. Measures must therefore be taken to prevent the synchronization word from being imitated by certain bit sequences. look in the information and separation boxes. For this purpose, a unique blocks of synchronization bits, i.e. synchronization bits that are not in the the formation and separation bit sequences, are selected. Sequences that do not meet the requirement of d-condition or k-condition is not so attractive for this purpose, then 456 708 - M the information density or the self-clocking properties are thereby affected negatively tivt. However, the choice is very limited within the group of sequences meets the (d, k) condition requirements.

A different method is therefore proposed. The block of synchronization bits contains a number of times e.g. at least twice in a row and consecutively a sequence comprising takes s bits of type "0" between two sequential bits of type "1." Preferably, s = k.

Fig. 4 shows a block of synchronization bits SYN. The block includes two times in a row and consecutively a sequence (IOOOOOOOOOO, 1 followed by 10 zeros) denoted by SYNP1 and SYNP2, respectively. This sequence can also is in the channel bitstream, namely for sequences where k = 10. To prevent the sequence of appearing twice consecutively and consecutively outside the block of synchronization bits, however, the first indication signal is suppressed then the sum of the number of separation bits and the number of sequential and consecutive information bits of type "0" immediately preceding a bit of type "1", the later forming part of the block of separation bits, is equal to k and also equal to the sum of the number of consecutive and sequential bits of information of type "D" immediately following said piece of type "1" in the block of the separate rationsbitar. The second already stated way to prevent imitation would be to use the sequence IOODOOOGDODO twice in succession, thus 1 sequence of ll zeros.

In addition, the block of synchronization bits also includes a block of synchronization separation bits. The function of the block of separation bits is exactly the same as the function of the block off described above separation bits between the blocks of information bits. Consequently, they have to task to meet the (d, k) condition and to limit DC imbalance requirement. The measures taken to prevent synchronization patterns from being the year is imitated in the stream by channel bits, as it occurs twice in succession and consecutively, these measures also prevent this pattern from occurring three times times before or after the block of synchronization bits.

The method described above, which can also be referred to as modulation _or coding, do the opposite direction, ie demodulation or decoding much easier. Limitation of the direct current imbalance has been performed without affecting blocks of information bits, so that the information in the separation blocks is levant for the demodulation of the information. In addition, there are choices made at the modulator end which m bits long blocks of data bits that have been assigned one given n1 long blocks of bits of information of importance not only for the modulator but also for the complexity of the demodulator. In magnetic recording systems are 456 708 the complexity of the modulator and the demodulator are of equal importance, as they measure fl5 n The same device- In optical recording systems, recording the "read-only" type medium so that the consumer device does not have to contain any denodulator. In the latter case, it is therefore of particular importance that reduce the complexity of the demodulator as much as possible even at the cost of a higher complexity of the modulator. .

Fig. 5 shows an embodiment of a demodulator which denodulates the blocks with 8 data bits from the blocks with 14 information bits. Fig. Sa shows a block diagram for the modulator and Fig. 5b schematically shows a part of the coupling. The demodulator includes AND gates 17-0 to 17-51 each with one or more inputs.

One of the 14 bits in the blocks of information bits is fed to each input, which are of the inverting or non-inverting type. Fig. 5b shows in column çí how this is done. Column 1 represents the least significant bit position C1 in the 14-bit information block, column 14 the second most significant bit position C14 and intermediate columns 2-13 represent the remaining bit positions fl ä with an S19 fl lflkë fl Silver that corresponds to the position. Rows O-51 refer to the AND gate tal, i.e. line 0 refers to the input format to the AND gate 17-0, line 1 refers to the input the walk format to the AND gate 17-1 and so on. A symbol 1 in the 1st column of line j indicates that the jze AND gate 17 is fed via a non-inverting input with the contents of the 1st bit position Bl. A symbol 0 in the 1st column of line j indicates that the jze AND gate 17 is fed via an inverting input with the contents of the 1st bit position (Ci). Consequently, an inverting in- time (row 0) on AND gate 17-0 connected to the 1st bit position (Cl) and a non-inverting input is connected to the 4th bit position (C4); and (row 1) a non-inverting input on AND gate 17-1 is connected to it 3rd bit position (C3); etc.

The demadulator further comprises 8 OR gates 18-1 to 18-8 which are passages are connected to the AND-gates 17-D to 17-51 outputs. Fig. 5b shows in column Ai how this is realized. Column A1 refers to gate 18-1, co- column A2 refers to gate 18-2 .... and column A8 refers to gate 18-8.

A letter A in the ith column of the jze row indicates that the 17-j r of the and-gate output is connected to the input on the OR-18 gate.

For AND gates 17-50 and 17-51, the circuit is modified as follows.

Inverting outputs on both AND gates 17-50 and 17-51 are each connected to an input of an additional AND gate 19. An output of the OR circuit 18-4 is connected to another input on AND gate 19.

Each output on the OR gates 18-1.18-2.18-3 and 18-5 to 18-8 and a output on the .0CH gate 19 is connected to an associated output 20-1. It decodes the block with 8 data bits consequently appears in parallel form on these outputs. 456 708 16 The demodulator shown in Fig. 5a may alternatively be in the form of a so-called FPLA (field programmable logic array) 'e.g. Signetics bipolar FBLA type 825100/825101. The table shown in Fig. 5 is the programming table for this "array". U The demodulator shown in Fig. 5 is excellent due to its simplicity suitable for "read only" type optical recording systems.

The block of synchronization bits can be detected with those shown in Fig. 6 the means. The transmitted or read recorded signal is fed to one input terminal 21. The signal is in i.NRZ-M (sheet) format. This signal is fed directly to a first entrance on an OR gate 22 and to a second entrance on or the gate 22 via a delay element 23. A so-called NRZ-I signal appears there- at the output of the OR gate 22 which is connected to the input of a shift register 24. The shift register comprises a number of sections each with one socket, which number is equal to the number of bits present in the block of synchronous serings- bits. In the example used above, the shift register shall have 23 sections "more specifically to contain the sequence IOOOOOOOOODIOOODDDODOOI. Each socket is connected to an input on an AND gate , which input is either an inverting or a non-inverting input.

When the synchronization sequence occurs at the AND gate 25 inputs, one arrives signal to be generated at an output 26 of this gate, which can be used as an indication signal for detecting the synchronization pattern. Nedelst this signal divides the direct current into blocks with (H1 + H2) bits V fi YdeVa ~ These blocks of channel pieces are shifted one after the other into a further one shift register. The most significant nl bits are read in parallel and fed to the inputs of the AND gates 17, as shown in Fig. 5a. The least significant The nz bits are irrelevant to the demodulation.

The coded signal is recorded e.g. on an optical recording medium.

The signal has a shape indicated by NF in Fig. 1b. The signal is applied to the recording medium in a helical information structure. Information structure the tour comprises a sequence of a number of superblocks, e.g. of that shown in Fig. 7 type. A superblock Sßi comprises a block of synchronization bits SYN¿ which block is realized in a manner shown in Fig. 4, and a number (in embodiment 33) blocks of channel bits, each with (n1 + n2) bits BCI, BC2 ... BC33. A channel bit of type "1" is represented by a trans- time in the recording medium, e.g. a transition from non-pit to pit; one channel bit of the type "0" is represented on the recording medium by the absence of transition. The helical information track is divided into elementary cells, N 45e 708 the bit cells. On the recording medium, these bit cells form a spatial structure which corresponds to a division in time (period time of a bit) of the current of channel pieces. '.

Regardless of the contents of the information and separation pieces, one can number of details are distinguished on the recording medium. For the medium, the k-condition means that the maximum distance between two consecutive transitions is k + 1 bit cells.

The longest pit (or non-pit) therefore has a length of (k + 1) bit cells. The d-condition means that the minimum distance between the two consecutive transitions is d + 1. The shortest pit (or not pit) therefore has a length of (d + 1) bit- cells. At regular intervals there is also a pit with a maximum length after- due to (or preceded by) the absence of a pit of maximum length. This structure luck is part of the block of sync bits.

In a preferred embodiment, k = 10, d = 2 and a superblock S takes 588 channel bit cells. The superblock SB¿ comprises a block of synchronizing ring bits with 27 bit cells and 33 blocks of channel bit cells each with 17 (l4 + 3) channel bit cells.

A modulator, a transmission channel, e.g. an optical recording medium, and a demodulator may together form part of a system, e.g. a sys- systems for the conversion of analogue information (music, speech) into digital information, which information is recorded on an optical recording medium. The on- the recording medium recorded information (or a copy thereof) can be reproduced by means of an arrangement suitable for reproducing the type of information recorded on the recording medium. _ The conversion circuit comprises in particular an analog-to-digital converter for to convert the analog signal (music, speech) to be recorded into a digital signal with a predetermined format (source coding). In addition, conversion contain part of an error correction system. In conversion circuit then the digital signal is converted to a format, by means of which the error in in particular occurs while reading the recording medium can be corrected in the arrangement for reproducing the signals. An error correction system that is suitable for this purpose is described in patent applications made by Sony Corporation in Japan under 14514, 21 May 1980 and 5 June 1980 respectively.

The digital, error-protected signal is then fed to the modulator which is described above (channel coding) for conversion to a digital signal which is adapted to the channel properties. In addition, synchronization the pattern and signal are brought to a suitable frame format. The so obtained the signal is used to generate a control signal, e.g. for a laser (NRZ- 456 708 m marking format), while a spire-shaped information structure is applied on the recording medium in the form of a sequence of pits / non-pits of a predetermined stämd ïëngd. '' is moth; for reproducing the piece of information derived from the recording the drawing medium or a copy thereof can be read by means of an arrangement meaiet. For this purpose, the arrangement comprises a modulator, which already has described in detail, the decoding part of the error correction system and a digital speech / anaiogomvandiare to return a copy of the anaïoga signal, which tiïlfö fi s conversion circuit.

Claims (14)

19,456,708 Patent claims A method of encoding a sequence of binary data bits into a sequence of binary channel bits, the sequence of data bits being divided into consecutive and sequential blocks (B01) each comprising m data bits, which blocks are encoded into sequential blocks of (n1 + n2) channel bits where (n1 + n2)> m, each of these blocks of channel bits (BC1) comprising a block of n1 information bits (B11) and a block of ng separation bits (BS¿), so that sequential blocks of information bits are always separated by a block of separation bits, while two sequential channel bits of a first type, type "1", are separated by at least d sequential and consecutive bits of a second type, type "0", and the number of sequential and consecutive channel bits of the the second type is not more than k, characterized in that the method comprises the following steps: -1- converting blocks containing m bits of data bits into blocks containing nl bits of information bits; Generating a group of possible sequences of channel bits, each sequence comprising at least one block of information bits and a block of separation bits, each possible sequence each comprising the blocks of information bits supplemented by one of the possible bit combinations of the blocks of separation bits; Determining the direct current imbalance for each of the possible sequences of channel bits determined in the previous step; Determination for each of the possible sequences of channel bits the sum I of the number of separation bits and the number of consecutive and sequential information bits of the type "0" immediately preceding a bit of the type "1" and the Sussen of the number following a bit of type "1", which bit forms part of one of the blocks of separation bits, and the sum of the number of separation bits and the number of consecutive and sequential information bits of type "0" immediately preceding and following this block of separation bits; Generating a first indication signal for the channel bit sequences whose values of the sums determined in the previous step are higher than d but not more than equal to k; -6- selection among the sequences of channel bits which resulted in the first indication signal, the sequence of channel bits which minimizes the direct current imbalance. Method according to claim 1, characterized in that the fifth step comprises the following sub-steps: 456 708 -5a- suppression of the first indication signal for the sequence of channel bits for which the sum determined in the fourth step of the number of separation bits and the number consecutive and sequential information bits of type "0" immediately preceding a bit of type "1" in the block of separation bits are equal to the sum also determined in the fourth step of the number of separation bits and the number of consecutive and sequential information bits of type "0" immediately follows a bit of type "1" in the block of separation bits, the sum of which is equal to s; and that the method further comprises the steps of: dividing a sequence of blocks of (n1 + n2) channel bits into consecutive and sequential frames each with p blocks; Inserting a block of synchronization channel bits SYN¿ between each two sequential frames, which block of synchronization channel bits comprises a predetermined block of n3 synchronization information bits, which block comprises at least twice in succession and sequentially a sequence between two sequential bits of type "contains s bits of the type" 0 "and further comprises a block of n4 synchronization separation bits, which block of separation bits is determined by performing the steps -2- to -6 ~ with respect to the block of synchronization channel bits. 3. A method according to claim 2, characterized in that s = k. A method according to any one of claims 1, 3, characterized in that the sixth step further comprises the sub-steps of: determining the accumulated direct current imbalance of the preceding blocks of channel bits; determining the absolute value of the sum of the accumulated direct current imbalance and the direct current imbalance for each of the sequences of channel bits resulting in the first indication signal. A method according to any one of claims 1 to 4, characterized in that the sequence of channel bits comprises four blocks of information bits each with n1 bits and four blocks of separation bits, that three blocks of separation bits have a first length nz 'and a block a length n2 "and that n2"> nl '. v A method according to claim 5, characterized in that n1 = 14, 456 708 21 n2 '= 2, n2 "= 6 and m = 8. A method according to any one of claims 1-4, characterized in that the sequence of channel bits comprises a block of information bits with nl bits and a block of separation bits with nz bits. A method according to claim 7, characterized in that n1 = 14, n2 = 3 and m = 8. A method according to any one of claims 1-4, characterized in that the sequence of channel bits is formed by at least two blocks of channel bits and that consecutive sequences of channel bits are jointly related to at least one block of channel bits. A demodulator for decoding the data bits encoded according to the method according to any one of claims 2 to 9, characterized in that it comprises: - means for detecting the synchronization pattern; - means for dividing the stream of channel bits into blocks with each (n1 + n2) channel bits; means for separating the blocks with nl information bits from the blocks with nz separation bits; means for converting a block with nl information bits into a block with m data bits. Demodulator according to claim 10, characterized in that the conversion means comprise AND gates (17-O ... 17-51), each AND gate having inputs to which the information bits coming from at least one predetermined bit position in the block of information bits, that the means further comprise OR gates (18-l ... 18-8) with inputs which are connected in a predetermined manner to the outputs of the AND gates and that these OR gates further have outputs for outputting the decoded AND gate bits in parallel. 12. A demodulator according to claim 11, characterized in that it further comprises a user device coupled to a m bit wide data path which is fed by said OR gates and which comprises a data bit block processing means. 456 708 22 13. A recording medium having an information structure comprising sequences of channel bit cells, each channel bit cells each containing a binary data bit represented by a level transition or no level transition at the beginning of the bit cell, characterized in that the maximum distance between two consecutive transitions is equal to the length of (k + 1) bit cells, that the minimum distance between two consecutive transitions is equal to the length of (d + 1) bit cells, that there are sequences of at most twice the maximum distance for (k + 1) bit cells and that the sequences are part of a synchronization sequence. A recording medium according to claim 13, characterized in that k = 10, d = 2; that the recording medium between two consecutive sequences which are at a maximum distance from each other comprises a frame with 561 channel bit cells, which frame comprises 33 blocks each with 17 channel bit cells and that the synchronizing sequence comprises 27 channel bit cells.