RU2025793C1 - Method of multichannel magnetic recording of digital information - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: first information pulses of first source are fed in to all N information channels. At initiation of readiness command from other L sources command to increase velocity of magnetic medium in L+1 times is formed. On completion of process of change of speed information pulses of first source are fed in to first N/(L+1) information channels and information pulses of other sources are sent into other L, N/(L+1) information channels. Simultaneously frequency of synchronization pulses is increased by L+1 times. On completion of readiness command other L sources stop formation of information pulses, from command to decrease speed of movement of magnetic medium by L+1 times. At same time frequency of synchronization pulses is diminished by L+1 times and information pulses of first source are fed into all N information channels. Method is meant for more effective use of magnetic medium with multichannel recording of information from several sources operating irregularly in process of multichannel magnetic recording of digital information by formation of synchronization and marker pulses, by extraction of auxiliary signals from them, by input of sign of antimisallignment marker into each information channel by summing information pulses with auxiliary signals, by summing of marker pulses in reference channel with synchronization pulses delayed by half-clock period and by subsequent formation of recording currents in all channels. EFFECT: increased efficiency of use of magnetic medium. 4 dwg

Description

 The invention relates to magnetic recording, and in particular to methods of multi-channel magnetic recording of digital information.

 A known method of magnetic recording of digital information (French patent N 2103834, class G 11 B 5/00) by adding the synchronizing and information pulses before generating the recording current. The known method with relative simplicity has low accuracy of the result of magnetic recording of digital information.

 There is also known a method of magnetic recording of digital information (Japanese patent N 52-4449, class 102 E 215.2, 1977) by adding information pulses with auxiliary signals obtained by converting synchronizing pulses, and the subsequent formation of the recording current. This method with relatively high recording accuracy has a low information recording density.

 The closest in technical essence to the described is a method of magnetic recording of digital information (as USSR AS N 879644, class G 11 B 5/09, application. 19.03.80) by generating clock pulses and marker pulses, receiving auxiliary signals from them, introducing an anti-skew marker in the information channel by adding information pulses with auxiliary signals, adding marker pulses in the reference channel with sync pulses delayed by a half-cycle, and the subsequent formation of recording currents. The known method with relatively high accuracy and longitudinal recording density has low functionality that reduces its technical characteristics.

 The aim of the invention is the multi-channel registration of information from several sources that operate irregularly.

 Figure 1 shows a structural diagram of one of the possible variants of the device with two sources of information; figure 2 - time diagrams of the change in speed of the magnetic medium; figure 3 - distribution of source information along the tracks of the magnetic medium; figure 4 - changes in the frequency of the clock.

 A device that implements the proposed method of multi-channel magnetic recording of digital information contains a serially connected clock source 1, a delay unit 2, the input of which is connected to the first input of the auxiliary signal generation unit 3, a marker pulse extraction unit 4, the second input of which is connected to the input of the clock source 1 and the first output of the control unit 5, and the third input to the output of the clock source 1, the addition unit 6, the first input of which is connected to the second input of the forming unit 3 in auxiliary signals, and the second input is to the third input of the auxiliary signal generating unit 3 and the output of the delay unit 2, and the recording amplifier 7, together constituting the reference channel 8, N information channels 9, each of which contains a block 10 for introducing an anti-skew marker and recording amplifier 11.

 The device also contains first and second sources of information 12 and 13, the outputs of which are connected through a switch 14, the control input of which is the second output of the control unit 5, to the first inputs of the blocks 10 for introducing an anti-skew marker of the first N / 2 information channels 9, the first inputs of the blocks 10 the second N / 2 information channels 9 are combined with the output of the source 12, the second inputs of the blocks 10 of all N information channels 9 are connected to the output of the auxiliary signal generating unit 3 and the tape drive (LPM) 15, information its inputs are connected to the outputs of the recording amplifiers 7 and 11, and the control input is with the third output of the control unit 5, the input of which is connected to the second output of the second information source 13.

 Magnetic recording of digital information according to the proposed method is as follows.

 Source 1 and blocks 2 and 4 form marker pulses, which are added by block 6 with delayed clock pulses and are registered through amplifier 7 to the reference track of the magnetic carrier in the CVL 15, block 3 forms a series of auxiliary signals from clock pulses and marker pulses.

 While the second source 13 does not generate information pulses, information pulses from the first source 12 (Fig. 3), through which the signs of anti-skew markers are introduced by blocks 10, are supplied to all N information channels 9 through the switch 14. Then these converted pulses through amplifiers 11 are fed to N information tracks of the magnetic carrier of the CVL 15.

At time t ₁ (figure 2), the second source 13 generates the beginning of the ready command, according to which the control unit 5 generates a command to increase the speed of movement of the magnetic medium in the CVL 15. After the acceleration time Δ t, the speed doubles (figure 2) . After a time interval t ₂ -t ₁ > Δ t, the control unit 5 generates a command to double the clock frequency (Fig. 4) and a command to the switch 14, which changes the structure of the diversity of information from the first and second sources 12 and 13 for all information tracks (figure 3). At time t ₃ (Fig. 3), the second source 13 completes the formation of the ready command, as a result of which the control unit 5 generates a command on the CVL 15 to halve the speed of movement of the magnetic medium and at the same time a command on the switch 14 to accommodate the information of the first source 12 for all N information tracks and a command to halve the clock frequency.

Claims (1)

 METHOD FOR MULTI-CHANNEL MAGNETIC RECORDING OF DIGITAL INFORMATION by generating clock pulses and marker pulses, receiving auxiliary signals from them, adding an anti-skew marker in each information channel, adding information pulses to auxiliary signals, adding marker pulses to the reference channel with a delayed half-pulse all channels of recording currents, characterized in that the information pulses of the first source are first fed to all N information channels, at the beginning of the readiness command from other α sources, form a command to increase the speed of movement of the magnetic medium by α + 1 times, send information pulses of the first source to the first N / (α + 1) information channels, and to other αN / (α + 1) information channels supply information pulses α of other sources, at the same time increase the frequency of clock pulses by α + 1 times, at the end of the ready command, other α sources stop generating information impulses lsy form a command to reduce the speed of movement of the magnetic carrier in the α + 1 times, simultaneously reduce the clock frequency at α + 1 times, and the first source data pulses supplied to all the N information channels.

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