SU1032461A1 - Device for simulating magnetic recording /reproducing path - Google Patents

Abstract

A DEVICE FOR MODELING A RECORD-PLAYBACK TRACT that contains serially connected random code generator, recording pulse shaping unit and -first differentiation unit, the outputs of which are connected respectively to the inputs of the first reproduction channel analog, consisting of two registers, the information inputs of which are inputs. analogue of the playback channel, the shift inputs of the registers are connected to the output of the reference frequency generator, and the bit outputs of the first and second registers are connected respectively, with the inputs of the first and second adders, the outputs of which are connected respectively to the inputs of the third adder, the output of the third adder is connected to the input of the low-pass filter, the output of which. It is an output of a reproduction channel analogue and is connected via a first pulse shaper to a first input of a measuring unit, characterized in that, in order to expand its functionality by reproducing the effect of transverse oscillations of a carrier on the accuracy of parallel digital recording, it additionally contains a second differentiation unit connected in series , the second analogue of the playback channel, the scaling amplifier, the voltage adder U and the second pulse shaper, the output of which is Connected to the second input of the measuring unit, the input of the second differentiation unit OO is connected to the second output of the block INS of recording pulses, the other input of the voltage adder is connected to the output of the first analogue of the playback channel.

Description

The invention relates to a computational specification and can be used to study the characteristics of a magnetic recording-reproduction path. A device for simulating a magnetic recording-reproducing path is known, which contains successively connected generators of a random code recording pulse generation unit, a differentiation unit, a pulse shaper, and a measurement unit for the characteristics of a sequence of pulses. The disadvantage of this device is low accuracy due to the fact that the differentiation unit and the low-pass filter as an analogue of the reproduction channel does not provide a sufficiently accurate path response to Noe reversal carrier. It is also known a device comprising two parallel circuits consisting of serially connected code sources, made in the form of shift registers with typed code values, write pulse drivers, differentiation units, low-pass filters and pulse drivers loaded on the measuring unit, 2. This device provides a determination of the effect of signal interference on parallel tracks of a carrier on interchannel time mismatch. However, its disadvantage should also be considered as the low accuracy of the model for the digital recording process of playing the Differential Unit and the low-pass filter. The closest proposed is a device for simulating a magnetic recording-reproduction path, containing successively connected random code generator, a shaping unit and a differentiation unit, the outputs of which are connected to registers connected to the inputs of adders loaded by a circuit from the legally connected third adder, lowpass filter, pulse generator and measuring unit G 3 J This device is characterized by high accuracy of simulation, however it has narrow functions. fessional capabilities of, as at 612, to determine the SOM is only the effect of interference signals on a magnetic recording playback time shifts voltage. The purpose of the invention is to expand the functionality of the device by reproducing the effect of transverse oscillations of the carrier on the accuracy of parallel digital recording. The goal is achieved by the fact that the device for modeling the magnetic recording-reproduction path, which contains series-connected random code generator, recording pulse generation unit and the first differentiation unit, whose outputs are connected respectively to the inputs of the first reproduction channel analog, consisting of two registers, information the inputs of which are the analog inputs of the playback channel, the shift inputs of the registers are connected to the output of the reference frequency generator, and the bits The outputs of the first and second registers are connected respectively to the inputs of the first and second adders, the outputs of which are connected respectively to the inputs of the third adder, the output of the third adder is connected to the input of a low-pass filter, the output of which is the output of the playback channel analog and connected to the first one to the input of the measuring unit, the second differentiation unit, the second analogue of the playback channel, a scaling amplifier, sum the voltage matrix and the 8th pulse generator, the output of which is connected to the second input of the change unit, the input of the second differentiation unit is connected to the second output of the recording pulse shaping unit, the other input of the voltage adder is connected to the output of the first analogue playback channel. FIG. 1 shows a block diagram of the device; FIG. 2 is a diagram of a reproduction channel analog; FIG. 3 shows timing diagrams, according to the method of digital recording under study; Figs are curves illustrating the effect of transverse oscillations of the carrier on temporal distortions of the reproduced signals. A device for simulating a magnetic recording-reproduction path comprises a random code generator 1 connected via a recording pulse shaping unit 2 to differentiation units 3. The outputs of the differentiation units 3 are connected to analogs of the k playback channels connected to the voltage adder 5 directly and through a scaling amplifier 6. The output of the adder 5 is connected via the second driver 7 and pulses to the second input of the measuring unit 8, the first input of which through the first driver 9 pulses under is connected to the output of the first analogue of the reproduction channel 4, the analogue of the reproduction channel (fig. 2) contains registers 10, the shift inputs of which are connected to the generator 11 of reference pulses, and the bit output s - to the adders 12, the Outputs of the adders 12 are connected to the third adder 13, the output of which through a low-pass filter 14 is connected to the output of the analogue. The device operates as follows. The random code generator 1 produces a random sequence of ones and zeros, which is fed to the input of the recording pulse generation unit 2. Unit 2 generates a pulse voltage corresponding to the recording current for the digital magnetic recording method under study (Fig. 3). Diagram a shows the recorded code sequence, Diagram 5 shows the change in carrier magnetization on the first track and Diagram 6 on the second. The diagrams (fig. 3) show that the unit is recorded by changing the magnetization of the nozzle on the first track (time txj), and the second track with a delay of time IT makes an additional change, the magnetization (time t2 ), and zero is recorded by changing the carrier value on the second track, followed by additional remapping of the carrier on the first track. The output voltages of the recording impulse formation unit 2 are fed to the differentiation units 3, which produce two sequences of short pulses depending on the sign of the derivative of the input signal. These pulses are fed to analogs A of the playback channels, which produce responses of the reproduction channel to changes in the carrier and carrier. This is done as follows. The pulses from the differentiation units 3 are fed to the registers 10 and using the generator 11 reference pulses are shifted through the bits of the registers that are connected to the inputs of the adders 12. Each input of these adders has its own specific weight, based on the desired form of the playback channel response to nchivanie carrier. Thus, at the output of one of the adders 12, the response of the reproduction channel is obtained to the remagnetization of the carrier in one direction, and at the output of the second in the opposite direction. In this case, the adder 12 does not generate a response. for one change in magnetization, and for some of them, determined by the ratio of the clock frequency Td of the signal recording the frequency of the reference oscillator pulses 11, the output signals of the adders 12 are subtracted by the adder 13, since the physically polarity of the responses to different magnetization reversals are opposite. The low-pass filter 14 smoothes the input signal, which is necessary due to the sampling of the channel response with a step determined by the frequency of the generator 11 reference pulses. Thus, the output voltage of the low-pass filter 14 is a reproduction signal for a given codeword on one of two tracks. Next, the analogs of the 4 playback channels are fed to the adder 5 directly and through the scaling amplifier 6, the gain factor of which is determined from the level of penetration of the playback signal of one track to another due to lateral vibrations of the carrier. The pulse shaper 7 generates a pulse of the zero derivative of the input signal, which is fed to one of the inputs of block 8 of. measurement. The second input of measurement unit 8 is connected to the output of one of the analogs of 4 playback channels through the second similar pulse shaper 9. Therefore, measurement unit 8 determines the temporal mismatch between the pulse, shape. of a signal from a single track, and a pulse formed from I10 of the sum of the signal of a given droshki and a signal of another track with a weight determined by the value of the specified transverse displacement of the carrier. The measurement result, which is the magnitude of the time error due to transverse movements of the carrier, is output to the input terminal of the device. In FIG. Figure 4 shows the calculated curves of the playback signals without interference. Curve 1 is the response of the playback channel to a single reversal of the carrier at time 1. (Fig. 3), dotted line 2 is the response of the channel to reversal of the carrier at time tg on the second track. In this case, the channel responses are approximated by a Gaussian curve expressing time Curve 3 1 represents the reproduction signal when the reproduction head reproduces the signal of its own track and the neighboring one with the same weights; curve 4 — the signal of another track is reproduced with a weight of 0.5; curve 5 - the signal of another track is reproduced with a weight of 0.25. These curves show that the shape of the sum signal is different from the original one: Gaussian, the slope of the sum signal decreases with increasing weight of the signal of the second track, and the pulse duration at the half amplitude level increases. In Fig. 4, it can be seen that the shift of the maximum of the total signal relative to the original signal (the value of l} increases with the weight of the signal of the second track.)

ABOUT- ,

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Claims (1)

A DEVICE FOR MODELING A RECORDING-PLAYING PATH, containing a random code generator, a recording pulse generating unit and a first Differentiation unit, the outputs of which are connected respectively to the inputs of the first analog of the playback channel, consisting of two registers, the information inputs of which are inputs of the analog of the playback channel , the shift inputs of the registers are connected to the output of the generator of the reference frequency, and the bit outputs of the first and second registers are connected respectively Especially with the inputs of the first and second adders, the outputs of which are connected respectively to the inputs of the third adder, the output of the third adder is connected to the input of the low-pass filter, the output of which is the output of the analogue of the playback channel and connected through the first pulse generator to the first input of the measurement unit, characterized in that, in order to expand the functionality by reproducing the influence of transverse oscillations of the medium on the accuracy of parallel digital recording, it additionally contains um series-connected second block swapping, the second analogue of the playback channel, a scaling amplifier, SU <, „1032461 a voltage adder and a second pulse shaper, the output of which is connected to the second input of the measurement unit, the input of the second differentiation unit is connected to the second output of the recording pulse formation unit, and the other input of the voltage adder is connected to the output of the first analogue of the playback channel.