AT404652B - METHOD FOR RECODING FOR TRANSMITTING OR RECORDING A DATA IMPULSE SEQUENCE, DEMODULATOR FOR DECODING A SEQUENCE OF IMPULSE BLOCKS DERIVED IN THIS METHOD, AND RECORDING CARRIER WITH AN ACCORDING TO THIS PROCEDURE - Google Patents

Description

ΑΤ 404 652 Β

The invention relates to a method for transcoding for the transmission or recording of a data pulse sequence, in which this data pulse sequence is divided into data pulse blocks, each containing a number m of immediately consecutive data pulses, and new pulse blocks are derived from these data pulse blocks, in which the information by two different pulse values are expressed '1' or '0', and in which these new pulse blocks are then subjected to transmission or recording, these new pulse blocks each containing a block of information pulses and a block of separation pulses, and the number m of information pulses and the number Π2 of the separation pulses taken together is greater than the number m of pulses of the data pulse blocks, with this derivation of the new pulse blocks to be subjected to transmission or recording, successive blocks of information pulses by only one each Block of separation pulses are separated, and the condition is met that two consecutive pulses having a first pulse value '1' are separated by a minimum number d of consecutive pulses having a second pulse value '0' and in the new pulse blocks the number of immediately consecutive pulses of the second pulse value '0' is limited to a preselected maximum value k (hereinafter called the d, k condition).

Furthermore, the invention relates to a demodulator for decoding a sequence of new pulse blocks derived according to this method and to a record carrier for magnetic or laser-optical reading, with a sequence of new pulse blocks decodable with this method with a demodulator according to the invention.

In digital transmission or in magnetic and optical recording / reproduction systems, the information to be transmitted or to be recorded is usually in the form of a sequence of characters. Together, these characters form the (often binary) alphabet. In the event that it is a binary alphabet (this alphabet is represented in particular by the characters '1' and '0'), this can be a character, for example the '1', according to the NRZ mark code on a Magnetic disk, a magnetic tape or a so-called optical disk can be set as a transition between two states of magnetization or focus. The other character, '0', is determined by the lack of such a transition. These signs correspond to the aforementioned impulses.

Due to certain system requirements, there are restrictions in practice for the consequences of impulses or signs that may occur. In some systems there is a requirement that the sequence of pulses or characters is self-clocking. This means that the sequence of the pulses or characters to be transmitted or recorded must have enough transitions to generate a clock pulse signal, which is necessary for detection and synchronization, from the pulse sequence. Another requirement may be that certain pulse sequences in the information signal should be avoided because these sequences are reserved for special purposes, for example as synchronization sequences. Imitation of the synchronization signal by the information signal impairs the uniqueness of the synchronization signal and thus the suitability for this purpose. Another requirement may be not to let the transitions follow one another too quickly to limit intersymbol interference.

In the case of magnetic or optical recording, this requirement can also be associated with the information density on the record carrier, because if the corresponding minimum time interval Tmin of the signal to be recorded can be increased at a certain minimum distance between two successive transitions on the record carrier, the information density becomes enlarged to the same extent. The minimum bandwidth Bmln that is required is also related to the minimum distance Tmin between transitions (Bmin = 1/2 Tmin).

If information channels are used which do not transmit direct current, as is usually the case with magnetic recording channels, this leads to the requirement that the pulse trains in the information channel have the smallest possible (or no) direct current component.

A method of the type described in the introduction is from the literature reference Tang, DT, Bahl, LR, " Block codes for a dass of constained noiseless Channels ", Information und Control, Heft 17, No. 5, December 1970, pages 436-461, known. This article relates to block encodings, where d-, k- or (d, k) -limited q-valued blocks of characters are assumed and the blocks meet the following requirements: (a) d-limited: two type-Ί ' - Characters are followed by a sequence of at least d consecutive

Type O’s separated; (b) k-limited: the maximum length of a sequence of consecutive characters of the type Ό ’is k.

A data pulse sequence is divided into immediately successive blocks of m data pulses each. These blocks of m data pulses are recoded into blocks of n information pulses, where n > damn. Because n > m, the number of combinations with n information pulses (2m) is greater than 2

AT 404 652 B as the number of possible blocks of data pulses (2m). For example, if the " d-limited " placed on the information pulse blocks to be transmitted or recorded, the mapping of the 2m blocks of data pulses to also 2m blocks of information pulses (from a possible number of 2n blocks) is selected in such a way that only those blocks of information pulses that are provided are mapped Fulfill the requirement (at least d zeros between two consecutive ones).

Table 1 on page 439 of the above-mentioned literature shows how many different blocks of information pulses are possible depending on the block length n and the demands placed on the size d. So there are 8 blocks of information pulses with a length n = 4 on the condition that the minimum distance is d = 1. Therefore, blocks of data pulses with a length of m = 3 (23 = 8 data words) could be reproduced by blocks of information pulses with a block length of n = 4, with two consecutive type '1' characters in the block of information pulses being represented by at least one type Ό ' Characters are separated. The coding for this example is then (the character <-> used below denotes the mapping of one block to the other and vice versa): 000 &lt; - &gt; 0000 001 &lt; - &gt; 0001 010 &lt; - &gt; 0010 011 &lt; - &gt; 0100 100 &lt; - &gt; 0101 101 &lt; - &gt; 1000 110 &lt; - &gt; 1001 111 &lt; - &gt; 1010

In the case of closed information words, however, in some cases the requirement (in the present example, the d condition) cannot be easily met. In the article mentioned, it is proposed to insert separating pulses between the blocks of information pulses. In the case of d-limited coding, a block of separating pulses with d pulses of type '0' is sufficient. In the example given above with d = 1, only one separation pulse (only a '0') is sufficient. Each block of three data pulses is then encoded into a new pulse block with 5 (= 4 + 1) pulses.

A disadvantage of this type of coding is that the proportion of low frequencies (including direct current) in the frequency spectrum of the current of the new pulse blocks, which are intended for transmission or recording in a channel and which are simply called channel pulses for brevity, is quite high is. Another disadvantage is that the code converters (modulator, demodulator) and in particular the demodulators are complicated.

In connection with the first-mentioned disadvantage, the article Patel, AM, "Charge-constrained byte-oriented (0,3) code", IBM Technical Disclosure Bulletin, Issue 19, No. 7, December 1976, pages 2715-2717, specifies that the DC component of (dk) -limited encodings can be limited by the fact that the new pulse blocks, ie the blocks of the channel pulses are connected by a so-called inverting or non-inverting element. The sign of the contribution of the currently existing block of channel pulses to the direct current component is thus chosen such that the direct current component of the previous blocks of channel pulses is reduced. However, this is a (d, k) -limited coding, the blocks of information pulses of which can immediately follow one another without affecting the (d.k) condition, as a result of which the addition of separating pulses is unnecessary for this reason.

The invention has for its object to provide a method of the type mentioned at the outset which improves the low-frequency spectrum properties of the signal to be derived from the new pulse blocks and enables the use of a simple demodulator.

The method according to the invention of the type mentioned at the outset is characterized in that after the conversion of the data pulse blocks into information pulse blocks for the formation of the new pulse blocks, a plurality of different separating pulse blocks of the same length are formed, of which those which are selected together are selected in a first selection with the adjacent information pulse blocks meet the d, k condition that the DC component is determined for each combination of these separation pulse blocks with the information pulse blocks, and that the combination with the lowest value of the DC component is selected from this in a further selection.

With these measures, the above objective is advantageously met, and a signal with favorable low-frequency spectrum properties or with a minimal DC component becomes available for the transmission of the recording. 3rd

AT 404 652 B

With regard to exact synchronization, in order to be able to clearly differentiate between information pulses and separation pulses when demodulating the transmitted or recorded signal, it is particularly advantageous if those combinations of separation pulse blocks and information pulse blocks for which the determined one is selected are eliminated in the first selection Sum of the number of information pulses having the second pulse value '0' and immediately preceding the respective separation pulse block and the number of immediately following Ό 'separation pulses, and the determined sum of the number of O'-pulse pulses immediately following a separation pulse having the first pulse value' 1 ' and 'O'-information pulses have a preselected value s, and that further a number of the new pulse blocks are arranged in immediately successive groups of p blocks each and a block of synchronization pulses between two successive groups pen is inserted, the block of synchronization pulses having a block of synchronization information pulses in which there is at least twice immediately successively a pulse sequence which between two successive pulses with the first pulse value '1' has a number s of pulses equal to the preselected value s with the second Pulse value '0', and further comprises a block of synchronization separation pulses, and this block of synchronization separation pulses with respect to the block of synchronization pulses in an analogous manner as the separation pulse blocks in the new pulse blocks are derived. For safety reasons, the preselected value s is preferably chosen to be equal to the maximum value k to which the number of pulses of the second pulse value '0' which follow one another in the new pulse blocks is limited. For minimizing the DC component, it has also proven to be advantageous if, when selecting the respective combination as the new pulse block that is to be transmitted or recorded, the stored DC component of the previous new pulse block is determined, and that the sum of this stored DC component and of the DC component of each new pulse block is determined, and only the size of this sum, but not the sign corresponding to the polarity of the DC component, is taken into account. It is also favorable for minimizing the DC component if at least two new pulse blocks are formed in a sequence and neighboring sequences of new pulse blocks have at least one new pulse block in common.

The present method advantageously enables the use of simply constructed demodulators for decoding sequences of new pulse blocks derived according to the invention, and a favorable design of such a demodulator is characterized by a series connection of a detection device for detecting the synchronization pattern in the sequence of new information pulses, one of the detection device synchronized distribution arrangement for dividing the sequence of the new pulse blocks into individual pulse blocks, each comprising a preselected number m + n2 pulses, a separation device connected to the distribution arrangement for separating the blocks containing the information pulses from the new pulse blocks, and one connected to the separation device Converter device for converting the information pulse blocks into blocks of data pulses. It is of particular advantage with regard to a construction of the demodulator with simple digital components, if the inputs of the converter device are corresponding inputs of AND gates, to which information pulses, which are assigned to at least one specific pulse point of the information pulse block, are supplied in parallel, and that the outputs the AND gates are connected to the inputs of OR gates, the decoded data pulses being emitted in parallel at the outputs of the OR gates.

Finally, a record carrier which is advantageous with regard to the clear synchronization when reading out and thus distinguishing between information and separation pulses and a minimal DC component in the recorded signal is characterized in that the maximum distance between two successive level transitions which correspond to pulse cells with the first pulse value '1' is the same the length of a maximum number k + 1 pulse cells, which maximum number k +1 is equal to the maximum value k increased by 1, the number of pulse cells immediately following one another in the new pulse blocks with the second pulse value '0', that the minimum distance between two successive ones Level transitions are equal to the length of a number d + 1 of pulse cells, which number d +1 is equal to the minimum value d increased by 1, the number of pulse cells with the first pulse value that follow one another in the new pulse blocks '1' separating pulse cells with the second pulse value is '0', and that double sequences each with the maximum number k + 1 of pulse cells are provided between two successive level transitions, and these double sequences together with synchronization separating pulses form synchronization pulse blocks which are identical to one another Numbers of new pulse blocks are separated.

It can be mentioned that GB 1 407 163 A describes a method for recoding in which the polarity of the output signal is only changed when two identical pulses 4 in the input signal

AT 404 652 B occur in succession. In order to prevent that in the case of longer sequences of pulse changes in the input signal (e.g. 0101010 etc.) no polarity changes occur in the output signal, e.g. such a block of seven or more pulses occurs, polarity changes are made at intervals of 1 * pulses.

GB 1,440,280 A also relates to an encoding device in which the encoding of the pulse in each case takes place as a function of the preceding and the following pulse.

Finally, GB 1 569 076 A describes a coding system in which the blocks of (2N-1) pulses are recoded into blocks with 2N pulses each. The usable blocks of 2N pulses are selected so that disadvantageous bit combinations (e.g. the combinations with pulses that all have the same value) are avoided.

The invention is explained below using exemplary embodiments and with reference to the drawing. 1 shows a few pulse sequences to explain an exemplary embodiment of the coding format used in the invention; 2 shows some further exemplary embodiments of the format of the coding for the channel in which the transmission or recording takes place, as can be used in the reduction of the DC component; 3 shows a flow chart to illustrate an exemplary embodiment of the method according to the invention; 4 shows a block of synchronization pulses for use in the method according to the invention; 5 shows, in a circuit diagram (FIG. 5a) or wiring diagram (FIG. 5b), an exemplary embodiment of a demodulator according to the invention for decoding the data pulses coded using the method according to the invention; 6 shows an embodiment of the device for detecting a sequence of synchronization pulses; and FIG. 7 shows an exemplary embodiment of a frame format for use in the method according to the invention.

1 shows some pulse sequences to explain the method for recoding a sequence of data pulses (Fig.la) into a sequence of new pulse blocks (Fig.lb). The sequence of data pulses is divided into successive, closed blocks BD. Each block BD of data pulses has m data pulses. As an example, m = 8 is chosen for the following explanation (see also Fig.la). The same applies to any other value of m. A block of m data pulses BDi (generally contains one of 2m possible pulse sequences.

Such pulse trains are less suitable for being recorded optically or magnetically directly, for various reasons. If two data characters of the type Ί ’, which are recorded on a 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 must not be too close together because of the mutual influence. This limits the information density. At the same time, the minimum bandwidth ΒπΙη is increased, which is required to transmit or record the pulse current when the minimum distance Tmin between successive transitions (Bmin = 1/2 Tmin) is small. Another requirement that is often placed on systems for data transmission and optical or magnetic recording is that the pulse train should have enough transitions to obtain a clock pulse signal from the transmitted signal with which synchronization can be brought about. A data word with m zeros, which in the worst case is preceded by a data word that ends with a number of zeros and is followed by a data word that begins with a number of zeros, would endanger the clock pulse extraction.

Information channels that do not transmit a direct current, such as magnetic recording channels, are also required to have the smallest possible direct current component in the data stream to be recorded. In the case of optical recording, it is desirable because of the servo controls that the low-frequency part of the data spectrum is optimally suppressed. In addition, demodulation is simplified if the DC component is low.

For the above and other reasons, a so-called channel coding is applied to the data pulse sequences before they are transmitted or recorded over the channel.

In the block coding mentioned at the outset, the blocks of data pulses which receive m pulses are encoded as blocks of information pulses which contain m information pulses. 1 shows how the data pulse block BD ;; into a block of information pulses Bl ,; is converted. An example is chosen here for m = 14. Because m is larger than m, not all combinations that can be formed with m pulses are used; combinations that do not match the channel to be used are not used. In the example given, of the 16,000 possible pulse blocks, only 256 pulse blocks need to be selected for the required one-to-one mapping of data input blocks to pulse blocks. Therefore, some requirements can be placed on the new pulse blocks. A requirement is that between two successive information pulses of a first type, type '1', within the same block Blj of ni 5

AT 404 652 B

Information pulses of at least d immediately consecutive information pulses of a second type, the type '0'. Table I on page 439 of the aforementioned Tang and Bahl article, in &quot; Information and Control &quot;, shows how many binary words there are depending on the value of d. The table shows that if m = 14 is selected, there are 277 words with at least two (d = 2) bits of type '0' between successive bits (of type '1'). When coding blocks of 8 data pulses, of which 28 = 256 combinations can occur, as new pulse blocks with 14 information pulses, the requirement d = 2 can therefore be met without any problems.

Closing the information pulse blocks Bl | is however not readily possible if the d-limitation is not only within a block B1 | of ni impulses, but also across the boundary of two successive blocks BI |, BI | + i. For this purpose, it is suggested in the article mentioned (page 451) to include one or more separating impulses between the blocks of the information pulses. It is readily apparent that if at least a number of '0' type separation pulses are picked up, which is equal to d, then the requirement of d-limitation for the whole sequence of information pulses is met. In Fig. 1 it is shown that a new pulse block BC &lt; consists of the block Blj of information pulses and a block BSj of separation pulses. The separation pulse block BSj has Π2 pulses, whereby the new pulse block BC &lt; has a total of m + n2 pulses. Unless otherwise specified below, n2 - 3 is selected as an example here.

In order to achieve the most reliable possible clock pulse generation, it can also be provided that the maximum number of type Ό'-pulses, which may occur continuously between two successive type '1' pulses within only one block B1 of information pulses, to a certain value k is limited. In the present example with m = 8 and m = 14, from the 277 words which correspond to the condition d = 2, for example those words can be eliminated which have a very large value for k. It turns out that k can be limited to 10. Therefore, a sequence of 28 (generally 2m) data pulse blocks of 8 (generally m) pulses each is mapped onto a sequence of also 28 (generally 2m) blocks of information pulses, which are also required by the requirement ^ 1 = 2 and k = 10 (generally “d, k - limited or” d, k - condition selected from 2U (generally 2) possible information pulse blocks. The assignment of each of the data pulse blocks BD | to only one of the information pulse blocks Bl | is on In the aforementioned Tang and Bahl article, the conversion of data pulses into information pulses is clearly defined in a mathematically closed form, and although this conversion is basically useful, a different assignment is preferred, as will be explained below

It is only possible to connect the channel pulse words ΒΙ (which are also k-delimited, as is the case for only d-limited impulse blocks, if separating pulse blocks are provided between the information pulse blocks Bl |. Basically the same separating pulse blocks BSi of Bits2 bits each can be used for this , because the requirements "d-limited" and "k-limited" are not opposing, but rather complementary, so the sum of the number of pulses of the type 'O' that precedes a certain separation pulse block BSi should be the number of pulses , which follows the separating pulse block BS |, and the Imp2 pulses of the separating pulse block BSi itself exceed the value k, at least one pulse with the pulse value '0' of the separating pulse block must be replaced by a pulse with the pulse value '1', so that the sequence of Zeros are divided into sequences that are each a maximum of k pulses long.

In addition to ensuring that the requirements of the d, k condition are met, the separation pulse blocks BSi can be dimensioned such that they can also be used to minimize the DC component. This is based on the knowledge that a certain format of the separating pulse block BSi is prescribed for some rows of information pulse blocks Blt, but that in a large number of cases there are either no requirements or only limited requirements for the format of the separating pulse block BSi will. The space created in this way is used to minimize the DC component.

The emergence and growth of the DC component can be explained as follows. The information pulse block Blt according to Fig.lb is set, for example in the form of an NRZ mark format on the record carrier. In this format, a '1' is recorded by a transition at the beginning of the relevant pulse cell and a '0' as &quot; no transition &quot; recorded. The in the information pulse block Bl | The pulse train shown then takes a form which is denoted by WF and in which this pulse train is recorded on the recording medium. This sequence has a DC 6

AT 404 652 B partly because in the relevant sequence the positive level exceeds the negative level in length. A measure that is often used for the DC component is the so-called DSV, the digital sum value ("digital sum value"). The DSV, provided that the levels of the waveform WF + 1 or -1 are equal to the running integral of the waveform WF and is + 6T in the example shown in Rg.1 b, where T is the length of only one pulse interval is. If such sequences are repeated, the DC component will increase. This DC 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 separating pulse block BS (is used as follows to limit the DC component. At a certain moment a data pulse block BD | is offered. This data pulse block is converted into an information pulse block B1 for example by means of a table stored in a memory a number of possible new pulse blocks BC, each containing (ni + 2) pulses, are generated These blocks BQ all contain the same block of m information pulses (pulse cells 1 to 14 inclusive, FIG. 1b), supplemented by the possible pulse combinations of the n2 separation pulses (Pulse cells 15, 16 and 17, Fig. 1b.) Therefore, in the example according to Fig. 1b 2 "* = 8 possible new pulse blocks are created. The following parameters are then determined from each of the new pulse blocks in an essentially arbitrary order: a ) It is determined whether the d-Bed for the relevant possible new pulse block in view of the previous pulse block ing and the k condition do not conflict with the format of the separation pulse block in question. b) it is determined how large the digital total value = DSV is for the possible new pulse block in question. A display signal is generated for the possible new pulse blocks that do not contradict each other in the requirement of the d and k conditions. The selection of the coding parameters ensures that such a display signal is generated for at least one of the possible information pulse blocks. Finally, from the possible new pulse blocks for which a display signal has been generated, for example, each new pulse block is selected which has the smallest DSV in absolute value. A better method, however, is to store the DSV of the previous new pulse blocks and to select the block from the new pulse blocks that are considered to be transmitted next that has the absolute value of the stored DSV decreased. The pulse word selected in this way is transmitted or recorded.

An advantage of this procedure is that the separation pulses that are already necessary for other purposes can also be used in a simple manner to limit the DC component. Another advantage is that the intervention in the signal to be transmitted is limited to the separation pulse blocks and does not extend to the information pulse blocks (apart from the polarity of the waveform to be transmitted or to be recorded). The demodulation of the read recorded signal then only needs to refer to the information pulses. The separation pulses can be disregarded.

Some further exemplary embodiments are illustrated in FIG. 2. 2a shows schematically a series of new pulse blocks BC1-1, BC |, BQ + i ..... which contain a predetermined number (m + n2) of pulses. The new pulse blocks BQ-1 etc. contain information pulse blocks of m pulses each and separation pulse blocks ..., BSj-2, BS, -i, BS |, BSi + i, ... of n2 pulses each.

In this exemplary embodiment, the direct current component is determined simultaneously over several blocks, for example, as also shown in FIG. 2a via two new pulse blocks BC) and BCi + i. The direct current component is determined in a manner corresponding to the exemplary embodiment according to FIG. that the possible formats of the superblocks are generated for each superblock SBQ, ie the blocks of the information pulses for block BQ and block BQ + i are with all possible combinations that with the πς separation pulses of the block BS | and the block BS ^ v can be added. The combination that minimizes the DC component is then selected from this set. An advantage of this procedure is that the remaining DC component has a more uniform character, because more than just a new pulse block shows in advance which intervention is optimal. A favorable modification of this method differs in that the super block SBC) (FIG. 2a) is shifted by only one new pulse block BCi after the DC component has been minimized. This means that the new pulse block BQ (in Fig. 2a), which is part of the super block SBC; forms, is processed and the following super block SBCI + 1 (not shown) contains the blocks BQ + i and BQ + 2 (not shown), whereby the minimization of the DC component shown above is carried out. The block BQ + i thus forms part of the super block SBQ and the subsequent super block SBCj + i. It is entirely possible that the (temporary) choice for the separation pulses of the block BSi + i in the super block of the SBQ deviates from the final choice in the super block SBQ + i. Because every 7th

AT 404 652 B new pulse block BC is used several times (twice in this example), the DC component and thus the noise component is further reduced.

Fig. 2b illustrates a further embodiment in which the DC component is determined over several blocks simultaneously (SBC), for example, as shown in Fig. 2b, over four new pulse blocks BCj (1 &gt;, BCj, 2), BCjt3 &gt; and BCj &lt; 4). These new pulse blocks each contain a certain number nt information pulses. The number of separation pulses generated in the separation pulse blocks BSj (1 &gt;, BSj &lt; 2), BSj (3) and BSj &lt; 4 &gt; are included, but is not the same for every new pulse block BCf. For example, the number of information pulses may be 14 and the number of separation pulses may be 2 for blocks BSj (1>, BSj <2>, BSj <3) and 6 for block BSj (4). The DC component is determined in a corresponding manner, as has been described for the exemplary embodiment according to FIG. 2a.

Another advantage of this method - in addition to the advantages already mentioned, which also apply in this case - is that the availability of a relatively long block BS of separation pulses increases the possibilities for limiting the DC component. In particular, the remaining DC component of a sequence of channel pulses, each channel new pulse block BC having an equal number of, for example, 3 separation pulses, is larger than the remaining DC component of a sequence of channel pulses whose separation pulse blocks have an average of 3 separation pulses, however distributed in 2-2-2-6 pulses.

It should be noted that the described time sequences of functions and associated states are in universal sequential order. Logic circuits can be implemented, such as commercially available microprocessors with assigned memories and with assigned peripheral devices. A flow diagram for such an implementation is shown in FIG. 3. The names of the blocks which explain the functions and the states of the coding method in chronological order include the following explanations, which are summarized in tabular form for the sake of simplicity. Column A shows the reference character, column B the logical name of the respective block and column C the explanatory text for the block in question. ; a B c 1 DSV: = 0 acc i: = 0 The digital total value (DSV) of the previous channel of new impulse blocks receives 8 · beginning the value zero. The first data pulse block BO receives the number i = 0. It continues with block 2; 2 BD. 1 The data pulse block BDi of m pulses with the number i is selected from a memory. It continues with block 3; 3 BI. (BD.) The data pulse block with the number i (BO ^) is converted into an information pulse block Bli of n ^ pulses (BI ^) by means of a table stored in the memory; continue with block 4; * »J: = 0 A parameter j is initially set to a value of 0; the parameter j is the number of one of the Qchannel new impulse blocks of + n? Inoulsen, who may be considered for transmission or recording; continue with block S; 17 8

AT 404 652 B A B C (continued) 5 ^: = j +1 or parameter j is increased by 1; block 6 follows. 6 j «LQ? If the relevant parameters are determined from all possible channel new pulse blocks, the process is continued, which is denoted by block 13. This is indicated in block 6 with the connection N. If j ^ Q is, continue to block 7; 7 Bcf.TBI. + BSJ 1 1 The J. th possible channel new pulse block BC ^ is formed by the information pulse 81ock ·? ' BIj. is supplemented with the jth combination of the separation pulse block BSJ; block 8 follows; 8 DSVJ =? The DSV of the jth possible channel new impulse biotit is determined; continue with block 9; 9 &gt; kJ &quot; ? max it. it is tested whether the jth possible new * pulse block when connected to the previous new pulse block BC._j meets the requirement of the k condition. If this request is fulfilled, then the process continues, which is indicated by block 10 (connection N). If this requirement is not met, the process is continued as indicated by block 11 (connection Y). 10 &lt; ? mt n It is tested whether the jth possible new pulse block when connecting to the previous channel new j pulse block BC ^ _- meets the requirement of the d condition. If this requirement is met, the process is continued as indicated by block 12 (connection N). If this requirement is not met, the process is continued as indicated by block 11 (connection Y); 9

AT 404 652 B A B C (continued) 11 DSV ^: = Max The DSV of the jth new pulse block is given such a high value (Max) that this new pulse block cannot be selected; block 12 follows; 1 2 DSC ^ WJ) + DSVacc The DSV of the J. -th new «impulse block (05V is added to the stored DSV (DSV) of the previous new impulse block to a new, stored value of the DSV (DSV ^ ^), the return to block 5 follows. 13 min / DSV / = DSV ^ 'The minimum value of the DSV of the Q possible new pulse blocks is determined, and it turns out that this is the DSV of £. -th new pulse block, continue with block 1k; t * i sc? The <fth new pulse block is selected from the possible blocks, and continues with block 15; 15 DSV: = DSv (?) Acc The stored value of the DSV (DSVacc> is set equal to the stored value of the DSV of the selected information pulse block; block 16 follows; 16 i: = i + 1 the number of the blocks of the data and information impulso. is increased by 1. It * returns to block 2; the cycle is now repeated for the following (t + l) .- block data pulses.

The flow chart described is applied to the embodiment of FIG. 1. Corresponding flow diagrams apply to the exemplary embodiment according to FIG. 2, taking into account the modifications already described.

In order to be able to make a difference when demodulating the transmitted or recorded stream of channel pulses between the information pulses and the separation pulses, current blocks of (Π3 + ru) synchronization pulses are recorded in the channel pulse, namely zwar3, synchronization information pulses and ru synchronization separation pulses. For example, a block of synchronization pulses is always inserted after a certain number of information and separation pulse blocks. After detection of this word, it can then be clearly determined at which pulse locations information pulses and at which pulse locations separation pulses are present. It must therefore be avoided that the synchronization word can be mimicked by certain pulse sequences in the information and separation pulse blocks. For example, a unique, i.e. block of synchronization pulses not occurring in information and separation pulse sequences can be selected. Episodes the 10th

AT 404 652 B does not meet the requirements of the d and k conditions, are less interesting because the information density or the self-clocking properties are then impaired. However, within the group of sequences that meet the requirements of the (d, k) condition, the choice is very limited.

A different approach is therefore proposed. The block of synchronization pulses, for example, has at least twice a sequence immediately following one another between two successive pulses of the type &quot; 1 &quot; s &quot; 0 &quot; having. Preferably s is k. 4 shows a synchronization pulse block SYN. The block contains twice a sequence 10000000000 (a "1" followed by 10 zeros), which is designated SYNP ,, or SYNP2. This sequence can also occur in the stream of channel pulses for sequences with k = 10. In order to prevent the sequence, however, from occurring twice immediately in succession outside of the sync pulse block SYN, the indicated display signal is suppressed if the sum of the number of separating pulses and the number of immediately consecutive information pulses of the type &quot; 0 &quot; which is immediately one pulse &quot; 1 &quot; which last-mentioned pulse forms part of the separating pulse block, is equal to k and is also equal to the sum of the number of immediately successive information pulses of the type "0", which correspond to the said pulse of the type "1" of the separation pulse block. The other option already mentioned would be to use a sequence 100000000000 (a &quot; 1 &quot; subsequent 11 zeros) twice. The synchronization pulse block SYN furthermore also has a block SYNS of synchronization separation pulses, the function of which corresponds to the above-described function of the block of separation pulses between the blocks of information pulses. (Therefore, they serve to meet the requirements of the (d, k) condition and the limited DC component). The measures taken to prevent the synchronization pattern from being mimicked in the sequence of channel pulses by occurring twice immediately in succession also prevent this pattern from occurring three times before or after the block of synchronization pulses.

The method described above, which is also referred to as modulation or coding, is in the opposite direction, i.e. greatly simplified when demodulating or decoding. The limitation of the direct current component has been achieved without influencing the information pulse blocks, so that the information in the separation pulse blocks is irrelevant for demodulation. Furthermore, the choice made on the modulator side which m-pulse data pulse block is assigned to which nt pulse information pulse block is important not only for the modulator but also for the demodulator. The choice depends on how complicated the demodulator is. In magnetic recording systems, the complexity of the modulator and the demodulator are of equal importance because generally both are 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 make the demodulator as simple as possible, possibly even at the expense of the modulator.

5 shows an exemplary embodiment of a demodulator which demodulates the blocks of 8 data pulses from blocks of 14 information pulses. Fig. 5a shows the block diagram of the demodulator and Fig. 5b schematically shows part of the wiring. The demodulator contains AND gates 17-0 to 17-51, each with one or more inputs. One of the 14 pulses of the information pulse blocks is supplied to each of the inputs, which may have an inverting design. In Fig. 5b, column C, shows how this is realized. Column 1 represents the least significant pulse position Ci of the 14 pulse information block, column 14 the most significant pulse position Ci 4, and the intermediate columns 2 to 13 represent the remaining significant pulse positions corresponding to their pulse position. Lines 0 to 51 refer on the order of the AND gates, ie Line 0 refers to the input format of the AND gate 17-0, line 1 relates to the input format of the AND gate 17-1 etc. A character 1 in the i-th column and j-th line means that the j.th AND gate is offered the content of the i.th pulse point Ci at a non-inverting input. A character 0 in the i-th column in line j means that the j-th AND gate is offered the content of the i-th pulse point (Ci) at an inverting input. Therefore, according to line 0, an inverting input of the AND gate 17-0 is connected to the 1st pulse location (Ci) and a non-inverting input to the 4th pulse location (C4); Furthermore, according to line 1, a non-inverting input of the AND gate 17-0 is connected to the 3rd pulse point (Cs).

The demodulator also contains 8 OR gates 18-1 to 18-8, the inputs of which are connected to the outputs of the AND gates 17-0 to 17-51. In Fig. 5b under the column A | indicated how this is accomplished. Column Ai refers to AND gate 18-1, column Az relates to AND gate 18-2, etc., and column As relates to AND gate 18-8. A letter A in the i-th column of the j-th line indicates that the output of the AND gate 17-j coincides with the input of the OR gate 18-i 11

AT 404 652 B is connected. For the AND gates 17-50 and 17-51 the connection is modified as follows. An inverting output of the AND gate 17-50 and the AND gate 17-51 are each connected to an input of a further AND gate 19. An output of the OR gate 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 to 18-8 and an output of the AND gate 19 are each connected to an output 20-i. The decoded block (BD;) of 8 data pulses is therefore available in parallel at this output.

5a can also be designed with 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 simplicity of the demodulator according to FIG. 5 is quite suitable for systems for optical recording of the "read-only" type.

The block of the synchronization pulses can be detected with a device which is shown in FIG. 6. The transmitted or read recorded signal is fed to an input terminal 21. The signal is in 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. A so-called NRZ-I signal is then available at the output of the OR gate 22, which is connected to the input of a shift register 24. The shift register 24 contains parts with one tap each, the number of which corresponds to the number of pulses that the synchronization pulse block has. In the numerical example explained above, the shift register must have 23 parts in order to be able to contain the sequence 10000000000100000000001. Each tap is connected to a possibly inverting input of an AND gate 25. If the synchronization pulse sequence is present at the inputs of the AND gate 25, a signal is generated at an output 26 of this AND gate 25, which signal can serve as an indication signal for detecting the synchronization pattern. With the help of this signal, the current of pulses is divided into blocks of (ni + ¾) pulses. These blocks of channel pulses are successively shifted into another shift register. The most significant m pulses are read out in parallel and fed to the inputs of the AND gates 17, as indicated in FIG. 5a. The least significant Π2 pulses are irrelevant for demodulation.

The coded signal is recorded on an optical recording medium, for example. The signal has a shape given by WF in Fig. 1b. The signal is attached to the record carrier in a spiral-shaped information structure. The information structure has a sequence of a number of superblocks, for example of the type shown in FIG. 7. A superblock SB 'contains a block of synchronization pulses SYN |, which is constructed as shown in FIG. 4, and a number (33 in this exemplary embodiment) of new pulse blocks BCi, BC2, ... BC33) each (m +02) Impulses. A "1 &quot; is represented by a transition in the record carrier, for example a transition to a depression; a "0" type pulse is represented on the record carrier by the lack of a transition. The spiral information track is divided into elementary lines, the impulse cells. These pulse cells form a spatial structure on the record carrier, which corresponds to a division in time (period time of only one pulse of the stream of channel pulses).

Regardless of the content of the information and separation impulse, a number of special features can be recognized on the record carrier. The k condition means for the carrier that the maximum distance between two successive transitions is k +1 pulse cells. The longest depression (or &quot; not &quot; depression) thus has a length of (k +1) pulse cells. The d condition means that the minimum distance between two successive transitions is d +1. The shortest depression (or the shortest part between two depressions) therefore has a length of (d + 1) pulse cells. Furthermore, a depression with the maximum length occurs at regular intervals, with a subsequent (or previous) non-recessed part with the maximum length as well. This structure forms part of the block of synchronization pulses. In a preferred embodiment, k®10, d = 2 and contains a super block SB | 588 channel pulse cells. The Superblock SB | contains a sync pulse block of 27 pulse cells and 33 &quot; new &quot; Pulse blocks of 17 (14 + 3) pulse 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, which is recorded on an optical recording medium. The information recorded on (or a copy of) this record carrier can be reproduced using an arrangement which is suitable for reproducing the type of information which is defined on the record carrier. 12th

Claims (8)

AT 404 652 B The converter contains in particular an analog-digital converter for converting the analog signal (music, speech) to be recorded into a digital signal of a certain 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 record carrier, can be corrected in the arrangement for reproducing the signals. The digital error-protected signal is then fed to the modulator (channel coding) described above for converting it into a digital signal adapted to the channel properties. At the same time, the synchronization pattern is supplied and the signal is brought into a suitable frame format. The 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 depressions of certain lengths is applied to the recording medium. The record carrier or a copy thereof can be read out with an arrangement for reproducing the information pulses extracted from the record carrier. For this purpose, the arrangement contains a demodulator, which has already been described in detail, the decoder part of the error correction system and a digital-to-analog converter for recovering a reproduction of the analog signal which is offered to the converter. 1. A method for recoding for the transmission or recording of a data pulse train, in which this data pulse train is divided into data pulse blocks (BDj), each containing a number (m) of immediately successive data pulses, and from these data pulse blocks (BD,) new pulse blocks (BCi ) in which the information is expressed by two different pulse values ('1' or '0'), and in which these new pulse blocks (BQ) are then subjected to transmission or recording, these new pulse blocks (BCj) each one Block (BL) of information pulses and a block (BS |) of separation pulses contain and here the number (m) of information pulses and the number (na) of separation pulses (BSi) taken together is greater than the number (m) of pulses of data pulse blocks ( BD |), whereby in this derivation the new pulse blocks (BCj) to be subjected to the transmission or recording are consecutive Bl ocke (BL) of information pulses are separated by only one block (BSj) of separation pulses, and the condition is fulfilled that two successive pulses having a first pulse value (Ί ') have a minimum number (d) of immediately consecutive, a second Pulse value ('0') having pulses are separated and in the new pulse blocks (BCj) the number of immediately consecutive pulses of the second pulse value ('0') is limited to a preselected maximum value (k) (hereinafter d, k condition called), characterized in that after the conversion of the data pulse blocks (BD;) into information pulse blocks (BL) for the formation of the new pulse blocks (BCj *) several different separation pulse blocks (BS *) of the same length are formed, of which in a first Selection those are selected, each of which together with the adjacent information pulse blocks (BL. Bli + 1) meet the d, k condition that the direct current component (DSV) is determined for each combination of these separation pulse blocks (BS1) with the information pulse blocks (BL), and that from this the combination with the lowest value of the direct current component is selected (DSV) is selected. 2. The method according to claim 1, characterized in that those combinations of separation pulse blocks and information pulse blocks are eliminated in the first selection, for which the determined sum of the number of the second pulse value (Ό ') having, the respective separation pulse block immediately preceding information pulses and the number of immediately following 'O'-separating pulses and the determined sum of the number of immediately following Ό'-separating pulses and O'-information pulses following a separating pulse having the first pulse value (' 1 ') have a preselected value (s), and furthermore a number of new pulse blocks (BQ) are arranged in immediately successive groups of p blocks each and a block (SYNj) of synchronization pulses is inserted between two successive groups, the block (SYNt) of the synchronization pulses having a block of synchronization information pulses in which at least twice immediately following a pulse sequence (SYNPi, SYIMP2) is present which, between two successive pulses with the first pulse value ('1'), has the same number (s) of pulses with the second pulse value ('O') as the preselected value (s), and further comprises a block (SYNS) of synchronization separation pulses, and this block (SYNS) of the synchronization separation pulses with respect to the block of the synchronization pulses is derived in an analogous manner to the 13 AT 404 652 B separation pulse blocks (BS,) in the new pulse blocks (BC |) becomes. 3. The method according to claim 2, characterized in that the preselected value (s) is equal to the maximum value (k) to which the number of immediately consecutive pulses of the second pulse value ('0') in the new pulse blocks (BQ) is limited, is chosen. 4. The method according to any one of claims 1 to 3, characterized in that when selecting the respective combination as a new pulse block (BQ1), which is fed to the transmission or recording, the stored Qieichstromanteil (DSV1) of the previous new pulse block is determined, and that the sum (DSVacc) of this stored direct current component and the direct current component of each new pulse block is determined, and only the size of this sum, but not its sign corresponding to the polarity of the direct current component, is taken into account. 5. The method according to any one of claims 1 to 4, characterized in that in each case at least two new pulse blocks (BQ) in a sequence (SBC); SBQ) are formed and neighboring sequences (SBQ; SBQ) of new pulse blocks (BQ) have at least one new pulse block in common. 6. Demodulator for decoding the sequence of new pulse blocks derived according to the method according to one of claims 1 to 5, characterized by a series connection of a detection device for detecting the synchronization pattern in the sequence of new information pulses, a distribution arrangement synchronized by the detection device for dividing the Sequence of the new pulse blocks into individual pulse blocks, each comprising a preselected number (m + Π2) of pulses, a separating device connected to the splitting arrangement for separating the blocks containing the information pulses from the new pulse blocks, and a converter device connected to the separating device (17-20 5a) for converting the information pulse blocks into blocks of data pulses. 7. Demodulator according to claim 6, characterized in that the inputs of the converter device (17-20) are corresponding inputs of AND gates (17) to the information pulses, the at least one specific pulse point (Ci, Cz, ... Cu) of the information pulse block are assigned in parallel, and that the outputs of the AND gates (17) are connected to the inputs of OR gates (18), the decoded data pulses being output in parallel at the outputs of the OR gates (18) . 8. Record carrier for magnetic or laser-optical reading, with a sequence obtained by a method according to one of claims 2 to 5, with a demodulator according to claim 6 or 7 decodable sequence of new pulse blocks, with sequences of pulse cells, each containing a pulse, its value is represented by a level transition or a missing level transition at the beginning of the pulse cell concerned, characterized in that the maximum distance between two successive level transitions, which correspond to pulse cells with the first pulse value (Ί '), is equal to the length of a maximum number (k +1) pulse cells is, the maximum number (k +1) equal to the maximum value (k) increased by 1 of the number of immediately successive pulse cells in the new pulse blocks (BQ) with the second pulse value ('0') is that the minimum distance between two successive ones Level transitions equal to the length of a number (d + 1) of pulse cells is which number (d + 1) is equal to the minimum value (d) increased by 1 of the number of pulse cells with the second pulse value ('O') immediately following one another and separating pulse cells with the first pulse value (T) in the new pulse blocks (BQ) and that double sequences (SYNPi, SYNP2) with the maximum number (k + 1) of pulse cells between two successive level transitions are provided, and these double sequences (SYNPi, SYNP2) together with synchronization separation pulses (SYNS) synchronization pulse blocks (SYN ) that are separated from each other by the same number of new pulse blocks (BQ). Including 5 sheets of drawings 14