KR100531781B1 - Method and apparatus for modulating digital data and medium for recording modulated data generated thereby - Google Patents

Abstract

The present invention uses the (d, k) constraints of the Run Length Limited (RLL) code to quickly and accurately determine the channel codeword to be modulated at the boundary between data blocks in order to record data on a record carrier. The present invention relates to a digital data modulation method / apparatus and a modulated data recording medium generated by using the same. To this end, the digital data modulation method according to the present invention receives an input of the last unit of a block consisting of predetermined units, and With reference to the modulation data table of the set unit, a block which does not violate the set k-constraint condition is obtained from a Run Length Limited (RLL) code having a (d, k) constraint.

Description

METHOD AND APPARATUS FOR MODULATING DIGITAL DATA AND MEDIUM FOR RECORDING MODULATED DATA GENERATED THEREBY}

FIELD OF THE INVENTION The present invention relates to digital data modulation, in particular to modulation at the boundaries between data blocks using (d, k) constraints of Run Length Limited (RLL) codes, in order to record data on a record carrier. A digital data modulation method / apparatus for quickly and accurately determining a channel codeword to be established and a modulated data recording medium generated using the same.

In general, among the methods of modulating data and recording on a recording medium, Non-Return-to-Zero-Inverted (NRZI) code is a magnetic flux of a recording medium when a signal detected by the recording medium is binary '0'. Indicates that there is no change, and if the signal detected on the recording medium is binary '1', it indicates that the direction of the magnetic flux recorded on the recording medium is reversed, thereby recording data on the recording medium and detecting or reproducing the recorded signal. do.

The recently used Run Length Limited (RLL) code is an extension of the NRZI code concept, and converts 8 bits (1 byte) of data into 16 bits of special code (codeword). Therefore, the denser the codeword is stored on the recording medium, the higher the data recording efficiency. For example, since 8 bits are 256 bit combinations and 16 bits are 65536 bit combinations, the RLL code uses the 65536 bits generated by 16 bits for the 256-bit combination number generated by 8 bits. Generated by converting to 256 of the number of combinations. In this case, the transformed data must satisfy the following constraints.

The first binding condition requires that there is a bit having a value of at least one '0' bit between consecutive bits having a value of '1'. For example, one data bit is three times larger than the data recording density stored without special conditions, so that the data recorded on the recording medium is recorded at a high recording density. In this case, the first binding condition may be a distance (or one bit close to another bit) to distinguish the magnetic flux polarity of the data bits recorded on the recording medium, even if data is recorded at a high recording density on the recording medium. Distance to allow). In other words, the first binding condition is a condition in which bits having a value of a series of '0' bits are continuously recorded on the recording medium, and interference does not occur between symbols when the recorded data is reproduced.

The second constraint condition limits the number of zeros between consecutive '1' bits and '1' bits. The second constraint restores a clock signal from the reproduced data by locking a phase lock circuit to the transitions as the reproduced data transitions.

The RLL code is represented by a (d, k) code, where d denotes the minimum number of bits having a value of '0' to be inserted between consecutive bits having a value of '1', and k is a number. The maximum number of bits having a value of '0' is inserted between consecutive bits having a value of '1'. For example, the code (1, 7) is a condition in which there must be at least one bit having a value of '0' between bits having a value of '1' written and a value of '1' written. It means a code that satisfies the condition that there must be 7 or less consecutive bits having a value of '0' between the bits. In this case, the bits encoded while satisfying the constraint are modulated into bits having a value of '1' for an edge transitioning from the high level to the low level or the low level to the high level of the data pulse, and there is no transition of the pulse. For the interval, bits are modulated with a value of 0 '. Therefore, the minimum reverse period of the data pulse is represented by (d + 1) T, and the maximum reverse period is represented by (k + 1) T. Here, T represents the bit time interval in the recording data stream. For example, in the code (d, k) = (1, 7), the minimum reverse period Tmin becomes 2T and the maximum reverse period Tmax becomes 8T.

As the recording density of the data recorded on the recording medium increases, the minimum region Tmin may include distortion in the recorded data stream because the minimum run 2T is continuously generated. In other words, the focus and normal slope factors of the 2T waveform output amplitude are smaller and more prone to distracting than the focus and normal slope factors of the amplitudes of the other output waveforms. Therefore, an error is likely to occur when the recorded data is reproduced.

As described above, when a data signal having an error is modulated, it becomes a channel data stream including a DC component when recorded. Then, for example, many error signals, such as tracking errors, easily appear in the form of variation or jitter when servo-controlling a drive of a recording medium such as a compact disc.

Therefore, if possible, a signal modulated with no DC components should be generated. To this end, a digital sum value (DSV) is controlled with respect to the source code.

The DSV is a sum of data streams generated after Non Return to Zero I (NRZI) modulation on source codes.

A method for recording and reading an audio signal on an optical or magneto-optical recording carrier uses Eight-Fourteen Modulation (EMF) or Eight-Fourteen Modulation Plus (EMF Plus).

The FM-modulated signal is a channel code word generated by converting a series of 8-bit data words into a series of 14-bit codewords and further inserting three-bit merging words. In other words, each of the 14-bit codewords has a minimum length (minimum '0' run length, d) of bits having a value of '0' between two consecutive bits having a value of '1'. Bits with a value of '0' and 2 must satisfy a constraint with a maximum length ('0' run length, k) of 10. In addition, in order for the constraints to be satisfied between the codewords, a 3-bit merging word is used. For example, for eight possible 3-bit merging words, four 3-bit merging words can be used. In short, 001, 010, 000, 100, and the remaining possible 3-bit merging words 111, 011, 101, 110 are not used because they violate the k (= 2) constraint.

By determining the merging words according to the above rules, the low frequency components of the modulated signal can be reduced.

However, in the digital modulation method according to the related art, even if the codewords input by controlling the DSV are converted into channel codewords, a boundary between blocks consisting of a plurality of codewords (that is, the last of one block) Between the codeword and the first codeword of the next block, the codeword cannot be modulated accurately and quickly into the channelword.

It is a primary object of the present invention to quickly write a channel codeword to be modulated at the boundary between data blocks using the (d, k) constraints of the Run Length Limited (RLL) code to write data to the record carrier. The present invention provides a digital data modulation method and an apparatus for accurately determining the same.

Another object of the present invention is to provide a digital data modulation method for quickly and accurately determining a channel codeword to be modulated at the boundary between data blocks using (d, k) constraints of Run Length Limited (RLL) codes; An object of the present invention is to provide a recording medium for storing digitally modulated data generated using the apparatus.

To this end, in the digital data modulation method according to the present invention, receiving the last unit of a block consisting of predetermined units, referring to the modulation data table of a preset unit, adjusting the limit length having a (d, k) binding condition (Run Length Limited, RLL) code, characterized in that a block is obtained that does not violate the set k-constraints.

The recording medium according to the present invention receives a last codeword of a block made up of predetermined units and refers to a modulation data table of a preset codeword, and adjusts a limit length having a (d, k) binding condition. Length Limited, RLL) code, the unit does not violate the above k-constraining conditions are obtained and stored.

The digital data modulation method according to the present invention comprises the steps of obtaining the end '0' run length of the last codeword of the current block, obtaining a start '0' run length corresponding to the starting coding state of the next block; Selecting only the codewords that satisfy the k-restriction condition by comparing the total '0' run length generated by summing the end '0' run length and the start '0' run length, respectively, and a preset k-restriction condition; Characterized in that it comprises a.

In the digital data modulation method according to the present invention, generating a plurality of intermediate sequences by adding different digital words to an input data word, and generating the plurality of intermediate sequences according to a preset m / n coordination ratio. modulating a sequence matching the (d, k) constraint, and a '0' run length following the previous (d, k) constraint matching sequence in the modulated (d, k) constraint matching sequences. and selecting the (d, k) constraint matching sequence to be recorded on the recording medium, excluding the (d, k) constraint matching sequence that does not satisfy the k constraint.

In accordance with another aspect of the present invention, a digital data modulation method includes generating a plurality of intermediate sequences by adding different digital words to an input data word, and generating the plurality of intermediate sequences according to a preset m / n coding ratio. modulating the (d, k) constraint matching sequence, and performing the modulated (d, k) constraint matching sequences with a '0' run length exceeding a kset value less than k used in the modulation step. Excluding the (d, k) constraint matching sequence having a matching sequence, and selecting the (d, k) constraint matching sequence to be recorded on the recording medium.

The digital data modulation method according to the present invention comprises: a generator for generating a plurality of intermediate sequences by adding different digital words to an input data word, and setting the generated plurality of intermediate sequences in a predetermined m / n. And including a selector for modulating a sequence matching a (d, k) condition according to a coding rate and selecting one (d, k) condition matching sequence from the modulated (d, k) condition matching sequences. It features.

In the digital data modulation method according to the present invention, a step of generating a plurality of intermediate sequences by adding different digital words to an input data word, and pre-set m / n coding of the generated plurality of intermediate sequences Two steps of modulating a sequence matching the (d, k) condition according to the ratio, and in the modulated (d, k) condition matching sequences, a '0' run following the previous (d, k) condition matching sequence. And a step (3) of selecting the (d, k) condition matching sequence to be recorded on the recording medium, excluding the (d, k) condition matching sequence whose length does not satisfy the condition of k.

The present invention uses the (d, k) constraints of the Run Length Limited (RLL) code to quickly and accurately determine the channel codeword to be modulated at the boundary between data blocks in order to record data on a record carrier. A digital data modulation method / apparatus and a recording medium for storing modulated digital data generated using the same are described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a digital data modulation apparatus according to the present invention, which receives a data word and generates a data sequence, and receives the data sequence to satisfy a constraint (d, k). A selection unit 200 for selecting a sequence, a modulation data storage unit 300 for storing modulation data for reference when the selection unit 200 selects a sequence satisfying a (d, k) constraint, and ( d, k) pre-coding unit 400 for receiving a sequence that satisfies the constraint condition to generate a run-length sequence suppressed low frequency components.

Here, the sequence generator 100 receives the data words and combines them with each other to generate a plurality of intermediate sequences, and an scrambler 102 that generates and outputs a data sequence by scrambling the intermediate sequences. ).

The selector 200 receives a data sequence output from the sequence generator 100 and generates a selectable (d, k) constraint matching sequence (d, k) constrained sequence (d, k) inputs the encoder 201 and the selectable (d, k) constraint matching sequence, such as a sync pattern, a string with long '0's, or a string with a long run of alternating Tmin. A judging unit 202 for judging whether or not a subsequence is included and a selector for selecting and outputting a sequence satisfying the (d, k) constraints based on the information determined by the judging unit 202 203.

On the other hand, the determination unit 202, the run length calculator 1 for receiving the selectable (d, k) constraint matching sequence to calculate the number of consecutive '0' (that is, '0' run length) and A synchronization detector (2) that receives the selectable (d, k) constraint matching sequence and detects that there is a predetermined sync pattern; A Tmin calculator 3 for calculating the run length of Tmin, a DSV calculator 4 for inputting the selectable (d, k) constraint matching sequence and calculating a DSV, and the selectable (d, k) constraint And a k-condition calculator 5 for receiving a conditional matching sequence and calculating a k-restriction condition between two consecutive sequences.

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The operation of the digital data modulation apparatus according to the present invention configured as described above will be described with reference to FIGS. 2 to 4 as follows.

First, Figure 2 is a block diagram showing a data unit (data unit) in one data block, Figures 3a-3b is a block diagram showing the structure of the channel block, the data according to the present invention, Figure 4 A flowchart illustrating a digital data modulation method.

As shown in FIG. 2, the data unit according to the present invention includes a codeword, a leading portion indicating the number of '0's in front of the codeword, and a' 0 'at the back of the codeword. It comprises a trailing portion (trailing portion) indicating the number of. In addition, a block formed by gathering the units forms predetermined block data B1, B2, ..., Bi, Bi + 1, ... together with other blocks as shown in FIG. 3A. .

When the blocks are connected as shown in FIG. 3A, as shown in FIG. 3B, the trailing portion T of the last unit of the current block Bi and the leading portion L of the first unit of the block Bi + 1 to be connected are pre-set. A block to be connected to the current block may be connected only if the k-constraints set in S are satisfied.

A process of forming the block data by connecting the blocks is described in more detail with reference to FIG. 4 as follows.

The k-condition calculator 5 compares the previously entered and stored selectable (d, k) constraint matching sequences to determine whether the k condition is met between the selectable (d, k) constraint matching sequences. Compares the '0' run length between the currently entered selectable (d, k) constraint matching sequences. That is, a '0' run of the trailing portion T of the previously inputted selectable (d, k) constraint matching sequence and the leading portion L of the currently inputtable selectable (d, k) constraint matching sequence. Compares k (= T + L), which is the sum of lengths, with a previously set kset, and if T + L> kset, discards the current sequence (ST1 to ST4 or ST5 and ST7) and accepts the new sequence Repeat. Therefore, if the (d, k) constraint condition is satisfied, the current sequence is selected (ST6). The sequence may be a unit included in one block, as shown in FIG. 2, and the process is performed on the units, and then the block is determined.

Here, the k-condition calculator 5 is a condition used when modulating from m bits to n bits based on the table of the (d, k) encoder 201 and k of a value k _SET smaller than the k value. You can also set a new condition. In the new setting, the k-condition calculator 5 checks whether there is a continuous '0' run beyond the set k _SET for the entire sequence, not just the sequence connection part. After setting a flag for the sequence, the sequence is output to the selector 203.

In this way, when modulating, even if set to a condition with a value smaller than k, for example, 2 ^r selectable (d, k) binding condition matching sequences are generated. k There is a sequence that satisfies the conditions of _SET . Then, the edge information of the recorded signal is recorded more often on average.

If the table used in the (d, k) encoder 201 is created under, for example, k = 14 condition, the k-condition calculator 5 selects among 9, 10, 11, 12, and 13. One value can be selected for the k _SET condition. If k _SET is too small, too small a value is excluded because there may be no sequence satisfying k _SET in the selectable (d, k) constraint matching sequence.

If the table condition of the (d, k) encoder 201 is, for example, k = 18, k _SET can select and use one of values between 9 and 17.

Therefore, some measured or calculated values as described above and calculated values and flags displayed by the synchronization detection are output from the determination unit 202 to the selector 203. The selector 203 then determines the last sequence to be selected and recorded based on the DSV associated with the input several measurements. At this time, the sequence having the flag set by the determination unit 202 is excluded from the selection object and one of the remaining selectable (d, k) constraint matching sequences is selected.

The (d, k) constraint matching sequence selected as described above is converted by the precoder 400 into a modulated signal through an NRZI precoding process, and the modulated signal transitions from '1' to '0'. Is generated from the selected (d, k) constraint conforming sequence, integrated into two modules with no transition, and then written to the recording medium.

On the other hand, in the modulation method according to the present invention as described above, when the (d, k) encoder 201 has a code modulation rate of s / c (s: source code, c: channel code), the input sequence is RLL. Modulated into channel codewords without violating the k constraints specified in code (d, k) of the code. Here, the (d, k) encoder 201 refers to the modulated data storage unit to modulate the channel codeword without violating the k constraint between neighboring codewords. In other words, in order to prevent the codeword from violating the k constraint condition at the boundary where two blocks are connected, the maximum value is determined by counting the number (vector v) starting with '0' of the codeword in each state.

Referring to the contents described in the present application (PCT / KR00 / 01292) filed by the applicant, a method for obtaining the vector will be described below.

As in the embodiment of the application, in the code table with 9/13 modulation rate, 13 coding states and d constraint 1, vector v is {9, 5, 3, 3, 2 , 2, 1, 1, 0, 0, 0, 0, 0}. That is, the vector means a run length value of the longest start '0' among the codewords of the corresponding coding state for each of the 13 coding states. As the first value, 'v (1) = 9' is the maximum number of bits having a value of '0' consecutively from the first bit among the codewords in coding state 1 (that is, the starting length of '0' run length). ) Means 9. Similarly, 'v (2) = 5' indicates that the start '0' run length value is 5 among the codewords in the coding state 2.

Thus, using the modulation data table in this manner, it is possible to obtain a vector (the number of bits having a starting '0' run length value coming into the next state).

Meanwhile, the vector v may be defined differently for each modulation data table according to the state.

In addition, a method of modulating a channel codeword between blocks in the same manner as the method of modulating a codeword into a channel codeword in the one block will be described in detail as follows.

In order to modulate the channel codeword without errors among the blocks, the codewords are modulated into the channel codeword to perform channel modulation on one block, and at the end of the block, a '0' run length value T is obtained. Obtain Since the next state U is known at this point in time, the vector v (U) of the next state is also calculated.

When the run length value T of the end '0' and the run length value L of the start '0' in the next coding state are added to the last codeword where one block ends, the predicted ' 0 'run length value (k = T + L). The predicted '0' run length value k is compared with a preset kset value, and if the predicted '0' run length value k is greater than the preset kset value, the input codeword is Excluded from the candidate of the channel codeword to be modulated.

Accordingly, the digital data modulation method and apparatus according to the present invention can accurately modulate data inputted through channels without errors.

In addition, digitally modulated data generated using the digital data modulation method / apparatus according to the present invention may be stored in a predetermined recording medium, and according to a predetermined codeword pattern found between blocks using the recording medium. Corresponding codewords may be immediately converted into channel codewords.

As described so far, a digital data modulation method / apparatus according to the present invention and a recording medium storing modulated digital data generated using the same are source code to be modulated with a channel codeword between blocks having a predetermined size. The word is determined quickly and accurately while satisfying the (d, k) constraints of the RLL code.

1 is a block diagram showing a digital data modulation device according to the present invention.

2 is a block diagram illustrating a structure of a channel codeword of one unit included in one data block according to the present invention.

3A-3B are diagrams illustrating the structure of data channel blocks according to the present invention.

4 is a flowchart illustrating a digital data modulation method according to the present invention.

** Description of symbols for the main parts of the drawing **

100: sequence generator

200: selection

300: modulated data storage unit

400: transposed coding unit

Claims (26)

K is set in the Run Length Limited (RLL) code having a (d, k) binding condition by receiving the last unit of a block composed of predetermined units, and referring to a modulation data table of a preset unit. Digital data modulation method, characterized in that a block is obtained which does not violate the constraint conditions. The method of claim 1, wherein the obtaining of the blocks that do not violate the set k-constraints is performed by: And calculating the k-constraints of the last unit of the block by adding the run length of the last unit of the block and the run length of the unit to be modulated to the next block. The method of claim 1, wherein the blocks Digital data modulation method comprising a plurality of units. The method of claim 1, wherein the unit Codewords, A leading part indicating the number of '0's in front of the codeword, And a trailing portion representing the number of '0's behind the codeword. The method according to any one of claims 1 to 4, And storing data modulated by the digital data modulation method. The last codeword of a block composed of predetermined units is input, and with reference to the modulation data table of a predetermined codeword, the above code is defined in a Run Length Limited (RLL) code having a (d, k) binding condition. A recording medium which obtains and stores units which do not violate the set k-constraints. The method of claim 6, wherein the obtained units The recording medium, characterized in that the modulated data. The method of claim 6, wherein the units that do not violate the set k-constraints, And a k-constrainment condition of the last unit of the block is calculated after the run length of the last unit of the block and the run length of the unit to be modulated are added to the next block. The method of claim 6, wherein the blocks A recording medium comprising a plurality of units. The method of claim 6, wherein the unit Codewords, A leading part indicating the number of '0's in front of the codeword, And a trailing portion representing the number of '0's behind the codeword. Obtaining the end '0' run length of the last codeword of the current block; Obtaining a starting '0' run length corresponding to the starting coding state of the next block; Comparing the total '0' run length generated by summing the end '0' run length and the start '0' run length, respectively, to select only the codeword that satisfies the k-restriction condition. Digital data modulation method comprising the step of. The method of claim 11, Obtaining the starting '0' run length corresponding to the starting coding state of the next block, And a start '0' run length of a unit having a maximum start '0' run length among all units included in the coding state by a corresponding value. The method of claim 11, And storing data modulated by the digital data modulation method. Generating a plurality of intermediate sequences by adding different digital words to an input data word; Modulating the generated plurality of intermediate sequences into a sequence meeting a (d, k) constraint according to a preset m / n coding ratio; In the modulated (d, k) constraint matching sequences, the (d, k) constraint matching sequence whose '0' run length following the previous (d, k) constraint matching sequence does not satisfy the k constraint is satisfied. Selecting (d, k) constraint matching sequences to exclude and write to the record carrier. 15. The method of claim 14, wherein the modulating step And scrambling the generated plurality of intermediate sequences. 15. The method of claim 14, wherein the modulating step For each input data word, r-bit-sized digital words are added, in which case every number of digital words that can be generated with r-bits are generated, and added to the input data word, so that intermediate sequences as many as r-bits are added. Digital data modulation method characterized in that the generation. Generating a plurality of intermediate sequences by adding different digital words to an input data word; Modulating the generated plurality of intermediate sequences into a sequence meeting a (d, k) constraint according to a preset m / n coding ratio; Excluding the modulated (d, k) constraint match sequences with a (d, k) constraint match sequence having a match sequence of '0' runlength that exceeds a kset value less than k used in the modulation step, Selecting (d, k) constraint matching sequences to record on the record carrier. 18. The method of claim 17, wherein said generating is And scrambling the generated plurality of intermediate sequences. The method of claim 18, wherein the generating step For each input data word, add an r-bit-sized digital word, and generate as many digital words as possible in r-bit size and add them to the input data word to generate intermediate sequences as many as r-bits. Digital data modulation method characterized in that. A generation unit for generating a plurality of intermediate sequences by adding different digital words to the input data word, The generated plurality of intermediate sequences are modulated into a sequence meeting a (d, k) condition according to a preset m / n coding ratio, and in the modulated (d, k) condition matching sequences, one ( and d) k) selector for selecting a condition matching sequence. The method of claim 20, wherein the generation unit An augmentor for generating a plurality of intermediate sequences by adding different digital words to each input data word, and a scrambler for scrambling each of the generated intermediate sequences. The method of claim 21 wherein the augmenter For each input data word, add a r-bit-sized digital word, and generate as many digital words as possible in the case of r-bits, and add them to the input data word, thereby adding as many intermediate sequences as for r-bits. Digital data modulator, characterized in that for generating. The method of claim 21, wherein the selection unit For each intermediate sequence, an encoder that modulates a sequence that meets the condition (d, k) at a coding rate m / n, A judging unit for deducting the modulated sequence according to the contents of the bits and the frequency of occurrence of a predetermined subsequence; And a selector for selecting a sequence for recording on the recording medium the lowest (d, k) condition matching sequence given by the determination unit among the modulated sequences. Generating a plurality of intermediate sequences by adding different digital words to an input data word; Modulating the generated plurality of intermediate sequences into a sequence meeting a condition (d, k) according to a preset m / n coding ratio; And In the modulated (d, k) conditional matching sequences, the (d, k) conditional matching sequence where the following '0' run length with the previous (d, k) conditional matching sequence does not satisfy the condition of k is excluded. And selecting (d, k) condition matching sequences to be recorded on the recording medium. The method of claim 24, wherein said first step And scrambling the generated plurality of intermediate sequences. The method of claim 24, In the first step, for each input data word, r-bit-sized digital words are added, and in the case of r-bits, all digital words are generated and added to the input data word in all cases where r-bits can be generated. Digital data modulation method for generating as many intermediate sequences as possible.