SU930369A2 - Method of magnetic recording and reproducing information represented by binary code - Google Patents

Description

I

This invention relates to digital magnetic recording and can be used in storage devices with movable magnetic recording media such as magnetic disks and tapes.

According to the main author. St. No. 711618 is known a method of magnetic recording and reproduction of information represented by a binary code, including a two-frequency rectangular carrier manipulation on each also units and nulls of a code, halving the frequency of P1 overdraft, recording carrier drops by changing the direction of magnetization of the carrier, playing the recorded signal and generating the pulse sequence at the extreme values of the reproduced signal, in which the pulses follow with three periods of duration equal to T, 1.5 T and 2T, followed by the recovery of a binary code from this sequence, the formation of a clock signal, the frequency of which is determined by the average frequency of the pulse sequence of the playback signal, the correction of the temporal distortions of the pulses of this sequence by the synchronization signal, and before the restoration of the binary code, the restoration of the two-frequency signal by entering the pulse sequence the reproduced signal of additional pulses, while between the pulses For periods with periods equal to T and 2T, additional pulses are inserted in the middle of the periods, and between pulses with periods of 1.5 T, alternately by 2/3 and 1/3 of this period, and in the first period equal to 1.5 T, over a period of 2T, an additional impulse is introduced by an amount of 2/3 period.

Claims (1)

The disadvantage of this method is that when it is used, the recovery of binary information in the presence of an anomaly in the playback signal, i.e. the presence of an address marker, is violated because the known pattern of the signal of the reproduced pulse sequence is violated, according to which in 21., periods with a duration of 1.5T are repeated an even number of times (O, 2, 4 ...). The violation of this pattern by the address marker is that it results in a reproduction signal between periods with a duration of 2T of one period of 1.5T. The purpose of the invention is to increase the reliability of the recovered information, in particular, the address measure information of the camera, while increasing the recording density. The goal is achieved by assigning a combination of the reproduced signal in the pulse sequence, pulses with periods IT, 1.5T, 2T and introducing into this sequence an additional pulse in the period 1.5T by the amount of 1/3 of the period from its beginning. On the fit. 1 shows a device that implements the proposed method; in fig. 2 - time diagrams of the device; in fig. 3 - the address marker in the composition of the two-frequency signal encoded according to OST 4G0.306.002, and unambiguous to this signal, the pulse sequences of the reproduced signal, obtained during its processing by the proposed method. The device (Fig. 1) contains a signal generator I, a source of 2 digital information, a converter of 3 codes, a shaper of 4 signals, an amplifier Recording Header 6, a playback head 7, an amplifier 8, a pulse shaper 9, an inertial generator of 10 signals, a counting trigger 11 , signal corrector 12, signal recovery unit 13 and binary recovery circuit 14. Block 13, in turn, contains a shift register 15, a decoder 16, elements AND 17-20, a countable trigger 21 and an ele-. MENT OR 22. The device works in the following way. The reference signal c (Fig. 2) from generator 1 (Fig. 1), digital information B from source 2, and the signal of the address marker B are fed to converter 3, where the square carrier t is two-frequency controlled according to the information signal. When the signal of the address marker B is applied, the rectangular carrier t is switched only on units in the middle of bit intervals B and the rectangular carrier i is forbidden to switch at the end of the bit intervals from which sync pulses are formed in the two-frequency signal (in the signal the missing switches are marked with asterisks In order to simplify the time diagrams (Fig. 2), the number of missing switches is reduced from five to three. The number of ones and zeros surrounding the address marker is also reduced, and the address marker is duplicated twice. Next, shaper 4, on unipolar carrier fronts, forms a new signal by doubling the frequencies, which is amplified by amplifier 6 and written to head 6 on magnetic carrier. The signal from the carrier is reproduced by the head 7 and is amplified in the amplifier 8 (signal 6, Fig. 2). Shaper 9 generates a pulse sequence. corresponding to the extreme values of the reproduced signal e. The signal is synchronized by an inertial generator 10, which monitors the oscillations of the clock frequencies of the signal 5 (s, caused by instability of the speed of movement of the information carrier. Correction of temporal distortions of the pulse sequence within + 0.25T is performed by the corrector 12, information waiting intervals (signals and K for which generates a computational trigger I1, which switches from the leading edges of the pulses of the sync signal e. During the information waiting intervals, within which the pulses of the signal G are placed, It receives information into corrector 12 (for example, pulses K1 and K2 of the signal AND pulses of L and P signals I and K, respectively), and the received information is carried out in the following intervals (pulses K1 and K2 of the signal L1 and pulses M and Q of signals And And K, respectively). As a result, the output of the equalizer 12 produces a corrected playback signal L1. Next, the signal L1 enters block 13, in which, when restoring a two frequency signal by inputting additional pulses, patterns of the reproduced signal are used. the pulse sequence, the conclusion is that between periods of 21, periods of 1.5T are repeated an even number of times (O, 2, 4 ...) and the IT period among the periods of 2T and 1.5T can alternate anywhere, with. any sequence and in any quantity. No additional pulse is determined by the requirement that in a two-frequency signal the distance between the synchronizing pulses is equal to IT. This requirement will be met if, during the recovery of a two-frequency signal for periods with durations of 2m and IT, an additional impulse is introduced in the middle of the period, and for periods with a duration of 1.5T, the distance of the input pulse from the beginning of the period is taken , 5Т, i.e. by the value of / 3 and 1/3 of this period, and for the first such period, arising after the 2T period, this distance is determined in IT, t, e. 2/3 of the period. To perform such input of additional pulses, the pulse sequence L1 undergoes a multiple shift of 0.5T using the shift register 15 and matching pulses of the corresponding shifted pulse sequences detected by the decoder 16 are received as additional pulses. In FIG. 2, the base for the restoration of the two-frequency signal is the sequence L8. The impulses of the signal M, entered in the middle of periods in the 2T of the L8 sequence, are generated by the decoder 16 when the pulses of the signals L6, L10 coincide and the signal inversion L8. (Pulses of the signal m, as well as all other additional pulses, entered into the sequence of the signal of the L8 zashg trikhovana). The signal W of additional pulses introduced in the middle of periods in IT is formed from signals L7 and L9, the signal O of additional pulses entered in even periods of 1.5 T and the signal n of additional pulses of signals entered in odd periods of 1.5 T are generated from the signals L6, L9 and L7, L10, respectively. The counting trigger 21, which is set to the initial zero position by the signal m, and switches from the three leading edges of the pulses of the signal O, provides passage through the element 18 for additional pulses from the signal n for odd periods of 1.5T, and through the element 19 for additional pulses from signal about for even periods of 1.5T. However, the presence of the signal of the address marker A causes in the signal L1 a single appearance of a period of 1.5 T inter-. dots with a duration of 2T, i.e., an odd number of times. This can be seen if we consider signals B and C (Fig. 3), representing two unambiguous variants of the signal L1, which are equally generated depending on the initial state of the trigger in driver 4. Comparison of signals B and C with signal A representing dual frequency the signal in which the address marker is encoded according to OST 410.306.002 allows us to assume that both of these signals represent the signal A after decreasing its frequencies into two. In both signals, a period of 1.5T between periods of 2T in a single quantity occurs once in the combination of 1T-1.5T-2T and once in the combination of 2T-1.5T-1T. If for the restoration of the two-frequency signal A in the periods I, 5T of these combinations, to insert additional pulses according to a known method, then the additional impulse, introduced in the period 1.5T at the distance IT from its beginning, coincides with the corresponding signal pulse A for the combination periods of 2T-1.5T-1T, and for a combination of 1T-1.5T-2T, this would coincide at a distance of 0.5T, i.e. 1/3 of the period from its beginning. Therefore, in order to properly restore the pulse sequence, the two-frequency signal A with the address marker, it is necessary to determine the presence of a combination of periods 1T-1.5T-2T and, if present, to exclude the introduction of an additional pulse in the period 1.5T at the distance IT from the beginning Its introduction at a distance of 0.5T, which does not contradict the known method, if the period of 1.5T in the combination of periods 1T-1.5T-2T is -countable (signal C). To accomplish this, in the example of implementation of the method, an element 17 is provided which forms the pulse of the signal of the signal p when 79 coincides with the pulse K2 of the signal L1, the framing period 2T on the right, the inversion of the signal LH twice shifted by 0.5T (relative to the signal L1), pulse h fourfold shifted by 0.5T (relative to the signal L1, then the displacements of all signals are counted relative to the signal L1) of the signal L5, framing the period of 2T to the left and simultaneously framing the period of 1.5T to the right, pulse g, sevenfold shifted by 0.5T signal L8, The frame has a period of 1.51 on the left and a simultaneously framing period in IT on the right of a pulse ninefold shifted by 0.5T of the signal L10, framing the period in IT on the left, (Similarly, it produces a; the coincidence of the pulses S, t, V, 2 of the signals L1, L5, L8 and LY, respectively, and the inversion of the signal LZ), So about-f, the element And 17 reveals a combination of 1T-J, 5T-2T periods and produces a signal pulse p at the beginning of the period of 1.5 t of the base signal L8, which puts the trigger 21 in one state. A high level, at the direct output of flip-flop 21, provides for the passage of a pulse of signal o through element -I 19, which is introduced as an additional pulse (signal T) in a period of 1.5 T, which is in the combination of periods 1T-1.5T-2T L8 at a distance of 0.5T, t, e. 1/3 of the period from the beginning of the region. Since the pulse of the signal, parallel, arrives in parallel to the counting input of the trigger 21, it switches it to the zero position by the falling edge, thus prohibiting the passage of the pulse signal P through the element 18, the FM element 22 combines the basic signal L8 and all sequences of additional pulses in signal Y, 698. after gating which by synchronization, at the output of element I 20, a two-frequency signal is received 4 The presence of an address marker in the restoration of a two-frequency signal is indicated by the missing sync pulses (their location in f chased marked by asterisks between the second-third-fourth-fifth units that corresponds to the absence three shift m in the signal i, between the same units of information, b). The binary information recovery scheme 14 from the recovered binary signal F generates a sequence of X binary information pulses, a code, and a sequence of sync pulses. Thus, when using the proposed method, an unambiguous restoration of the address marker information is ensured. The invention method of magnetic recording and playback of information represented by a binary code, by the author. St. No. 711618, characterized in that, in order to increase the reliability of the recovered information of the address marker, a combination of pulses with IT periods is made in the pulse sequence of the reproduced signal; 1.5T; 2T and an additional impulse is introduced into this sequence in the period 1.5T by the value of the period from its beginning. Sources of information taken into account in the examination 1, USSR Author's Certificate No. 711618, cl. G & 5/09, 1977 (prototype), " fl glllllgluglllggadjgllllJ 0 About q o It I I 1 r I M; iM fl 10 i g I mta y i a and-IJ-LTUJ JrySLriJ jyi .., .j ijr tgHTUgnj (ushgshp-, lzjt A A j n n n n "Л 1Т А - П innfOiru