RU2082220C1 - Method for digital magnetic recording - Google Patents

Abstract

FIELD: computer engineering, in particular, peripheral data storage devices on removable magnetic media. SUBSTANCE: method involves generation of source binary information sequence of recording signals, which duration is equal to encoded information characters. Source binary information sequence of recording signals is preliminary converted to sequence of numbers which are represented in number system with radix r which is greater than 2. duration of recording signals is equal to information characters of r- radix numbers. When source binary information sequence is converted, it is divided into groups of binary numbers which provide input code words of same length. They are converted to output r- radix words which correspond to shortest combinations of recording signals. Required redundant output r-radix code words conform to ratio between ratio of lengths of input and output words. In addition recording density may be further increased if during conversion of source binary information sequence of recording signals, most frequent input code words of different length are converted in output code words which have shortest combinations of recording signals. EFFECT: increased density. 3 cl, 1 dwg, 2 tbl

Description

 The present invention relates to the field of computer engineering, in particular to digital magnetic recording, and can be used in external storage devices on a movable magnetic medium.

 The method of digital magnetic recording largely determines such important characteristics of recording equipment as recording density, reliability of reproducible signals, energy consumption, mass, dimensions, cost.

 Known methods of digital magnetic recording by potential signals with saturation of the medium, providing self-synchronization during playback and not requiring preliminary demagnetization of the medium, for example, recording methods with a modified modulation frequency [1, 2] The disadvantages of these methods include the low information capacity of the recording signals, the large redundancy required for self-synchronization, a high frequency of magnetization reversal of the medium, low tolerance for phase distortion (detection window).

Known methods for digital magnetic recording, including the formation of the source binary information sequence of recording signals whose durations are identical to information symbols, i.e. in these methods, various symbols of the information code are represented by time intervals of different durations [3, 4]
The disadvantage of these known methods is associated with the use of a binary number system in them, which determines a relatively low recording density. The binary number system in the timer presentation of information [5] does not allow to implement a multi-interval recording method, in which the recording signal generation would be based on the use of three or more different time intervals between media magnetization reversal, since the information code does not contain other digits except “zero” and “ units. "

 Closest to the proposed is a method of digital magnetic recording, based on the conversion of the source data into a sequence of numbers with a given number of charges [7] However, this method has the disadvantages noted above.

 The objective of the invention is to provide a method of digital magnetic recording, free from the disadvantages of the known solutions. Achievable technical result in this case is to increase the density of recording information on a movable magnetic medium.

 The specified technical result is achieved by the fact that in the digital magnetic recording method, comprising generating from the original binary information sequence recording signals whose durations are identical to the information symbols, according to the invention, the initial binary information sequence is pre-encoded into a sequence of numbers represented in the number system with base r, more than two, while the duration of the recording signals is chosen identical to the information symbols after ovatelnosti r-ary numbers.

At the same time, it is preferable that when transcoding the initial binary information sequence, the base r of the number system used for transcoding is selected, the time interval t _i , where i 1, 2.r, is assigned to each of the information symbols of the r-ary code, the initial binary information is partitioned sequences from the group of binary symbols forming the input code words of the same length, and encode the input binary words and output code words of the same length as a group r-ichn symbols selected from the set of r-ary output codewords as corresponding to the shortest combinations of recording signals in duration, while the excess number of output r-ary codewords necessary to ensure such a choice is determined by the ratio of their length to the length of the input codewords.

In addition, it is also preferable that when transcoding the original binary information sequence, the base r of the number system used for transcoding is selected, the time interval t _i , where i 1,2.r, is partitioned, is assigned to each of the information symbols of the r-ary code binary information sequence into groups of binary symbols forming the input codewords of different lengths, and encode the input binary codewords into output codewords in the form of r-ary groups The letters, the codewords having a small occurrence probability of a random binary information sequence, is associated with the output code words selected from a plurality of r-ary codewords output as corresponding to the shortest recording combinations of signal duration.

 The achievement of the above technical result is explained by the fact that number systems with a base of more than two have a large specific information density (the amount of information per character). Simultaneously with the growth of the base of the number system, the frequency of magnetization reversal decreases, which is necessary for the presentation of information at time intervals of a certain duration and sufficient to ensure self-synchronization during playback. This ultimately leads to increased reliability of the recording and prolong the life of the storage device.

 In this case, the use of r-ary codewords corresponding to only the shortest combinations of recording signals in duration leads to an additional increase in the recording density. In addition, this leads to an improvement in self-synchronization during reproduction due to the fact that shorter duration signals prevail in the obtained sequence of recording signals.

 An even greater effect of increasing the recording density is achieved if the input code words are ranked by the probability of their occurrence in a random (hypothetical) binary sequence and, in accordance with such ranking (as the probability of occurrence decreases), they are assigned output r-ary code words corresponding to the same regular combinations of recording signals increasing in duration. The necessary difference between these probabilities is provided by the presence of input binary codewords of different lengths.

 To justify the differences and advantages of the invention, we will compare its distinguishing features with the features of the known method for a similar purpose, in which the input binary information sequence is converted into a ternary sequence [6] This uses the mapping of input binary code words 4 characters long into output ternary code words 5 characters long .

 The use in the compared recording methods of various algorithms for generating recording signals (in the proposed method by obtaining signals whose durations are identical to information symbols, and in the known method by representing information symbols by a certain number of recording current switching, i.e., magnetization reversal) provided not only their difference essential features, but also properties, a comparison of which shows the advantages of the proposed recording method. So, the signal generation algorithm in the known recording method does not allow a similar representation of digits, large two, i.e. transcoding using a number system with a base of more than three, due to a sharp increase in the influence of intersymbol interference. At the same time, in the method corresponding to the invention, a transition to the number system with a base of more than three (4, 5, 6, etc.) can be achieved, since here the representation of information symbols is determined only by the duration of the signal, and the introduction of a new information symbol ( digits) can be achieved by introducing a new, longer time interval. At the same time, the minimum time interval is preserved and the influence of intersymbol interference does not increase.

 To ensure self-synchronization during playback, the proposed method, in contrast to the known method [6], does not require preliminary group coding of input information to provide certain combinations of zero and one in the resulting sequence. This is because the timer presentation of information in the claimed method ensures the regularity of magnetization reversal of the medium, and therefore, self-synchronization during playback.

 Moreover, in the method corresponding to the invention, there is no need to pre-emphasize the recording signals, which is usually associated with the presentation of information symbols by a certain number of switchings of the recording current (magnetization reversal) and is not required when using the timer principle of information presentation.

 Thus, the combination of timer principles for presenting information with transcoding in number systems with a base of more than two provides new advantages in comparison with the principles inherent in each of the above principles of digital magnetic recording of the corresponding invention. Moreover, it is the use of the timer presentation of information that allows the use of the number system with a base higher than three in this combination.

 As can be seen from a comparison of the two indicated solutions, the known recording method does not provide for the selection of output codewords providing the highest recording density. Moreover, the algorithm for generating recording signals used in it uses output code words corresponding to the same recording signals in duration, which excludes the possibility of choice. In the method according to the invention, due to the timer presentation of the information, it is possible to select the output code words corresponding to the shortest combinations of recording signals in duration, which ensures an increase in the recording density.

 The invention is further explained in the description of examples of its implementation, reflecting the use of the ternary number system.

 The proposed drawing shows the timing diagrams of the recording signals by the proposed method in comparison with the recording method with a modified frequency modulation.

 According to the invention, the initial information in the form of a binary information sequence A with a duration of a bit interval T (see drawing) is divided into groups of three binary symbols of input code words. Each such group is replaced by a group of two ternary symbols (C) of the output codewords. The coding table used (Table 1) is a mapping of input binary code words 3 characters long into output ternary code words 2 characters long. On the one hand, the mapping specified by Table 1 is a mapping of the input binary codewords to the output ternary codewords corresponding to the shortest combinations of write signals, since the redundant ternary combination 22, determined by the choice of the ratio of the lengths of binary and ternary codewords 3: 2 and corresponding to the most long-lasting combination of recording signals, not used. On the other hand, the corresponding binary and ternary codewords in the coding table are representations of the same non-negative integer in binary and ternary number systems, respectively. Thanks to the latter, ease of implementation of the encoding and decoding unit of the storage device is provided.

 Each ternary symbol of the output codeword is recorded on a magnetic medium with a potential recording current signal for a time interval equal to, for example, 1T for zero, 1.5T for unity and 2T for two (D). Thus, the total recording signal is three-integral, containing three different time intervals between switching the recording current (1T, 1,5T, 2T), and each switching necessarily coincides with the border or the middle of the measure T.

 When reproducing information recorded by the proposed method, a continuous signal is generated. Its modulation includes peak detection by differentiating the signal, followed by a symmetric limitation in a comparator with a zero switching threshold. Differentiation provides a zero crossing in accordance with the peak of the pulse. The final restoration of the ternary sequence is carried out by measuring the time intervals between successive transitions through zero. The initial binary sequence is obtained by the inverse transformation according to the specified table after preliminary ternary sequence splitting into groups of two characters.

The described recording method can be compared with the recording method with modified frequency modulation, which is widely used in computer floppy disk drives, as well as a three-interval method that allows the use of only three time intervals between switching currents of recordings of 1T, 1,5T, and 2T duration (B). Under the condition of recording random binary information by the proposed method, the relative increase in recording density is about 5%, while the magnetization reversal frequency of the medium decreases by about 8%
The recording method according to the invention, comprising the modified transcoding procedure described in paragraph 3 of the claims, can be implemented as follows.

 The original binary information sequence (A) is formed into a ternary sequence (E) by adaptive transcoding in accordance with the table (Table 2), which is a mapping of input binary code words of variable length (2.3 or 4 characters) to output ternary code words variable length (1 or 2 characters). The coding table is based on the mapping principle, in which the input code words that have the greatest probability of appearing in a random information sequence (i.e., in which zeros and ones appear independently and with the same probabilities of 0.5) are displayed on the weekend codewords corresponding to the shortest combinations of recording signals. For this recoding, groups of two, three or four binary characters are analyzed in the original binary sequence.

 Further generation of the recording signals (D), as well as processing of the playback signals, are similar to the above-described embodiment of the invention.

 Recovery of the original binary information is performed by reverse transcoding according to the same table (Table 2), for which one or two characters are analyzed in a ternary sequence read from a magnetic medium.

 Compared to the recording method with a modified modulation frequency, this adaptive coding method, provided random binary information is recorded, provides a relative increase in recording density by more than 10% and also a decrease in the frequency of magnetization reversal of the medium.

 Most effectively, the present invention can be used in external computer storage devices, in particular in magnetic disk drives.

Claims (3)

 1. The method of digital magnetic recording, which consists in preliminary transcoding the source binary information sequence into a sequence of numbers with a given number of bits, forming from the obtained sequence of recording signals with a duration identical to the information symbols of the sequence, and in recording the received signals, characterized in that during preliminary transcoding a sequence of numbers is represented in a system with a base r greater than two, and the duration of the recording signals in Sequences of r-ary numbers are chosen identical to information symbols. 2. The method according to p. 1, characterized in that when transcoding the source binary information sequence, for each information symbol of the r-ary code, the time interval t _i , where i 1, 2 r, is divided into the source binary information sequence into groups of binary symbols in the form input code layers of the same length, which are transcoded into output code words of the same length in the form of groups of r-ary characters selected from the set of r-ary output code words, as corresponding to the shortest in length the combination of recording signals, and the excess number of output r-ary codewords necessary to ensure such a choice is determined by the ratio of their length to the length of the input binary codewords. 3. The method according to p. 1, characterized in that when transcoding the source binary information sequence, for each information symbol of the r-ary code, the time interval t _i , where i 1,2 r, is divided into the source binary information sequence into groups of binary symbols in the form codewords of various lengths that encode into output codewords in the form of groups of r-ary characters, with input binary codewords having the highest probability of occurrence in a random binary information sequence In particular, assign output codewords selected from a plurality of r-ary output codewords as corresponding to the shortest recording signal combinations in duration.

Images