SU1269204A1 - Device for checking vow and flutter in magnetic tape recorder - Google Patents

Abstract

The invention can be used to tune and control a tape drive mechanism. The purpose of the invention is to increase the accuracy of control of the detonation of a magnetic recording apparatus. The device contains a band-pass filter I, threshold element 2, trigger 3, delay line 4, registers 5 and 15, element 6, generator 7 of the reference frequency, counters 8, 9, 14 and I5, converter 10, filter II, comparator 12 and digital-analogue converter I3. The introduction of new elements and the formation of new connections between the elements of the device make it possible to increase the accuracy of control of detonation by measuring the average value of detonation and eliminating the effect on the result of monitoring the fallout of signals during playback of the test waveform. I il. (L 1C O5 with ISD

Description

The invention relates to instrumentation engineering and can be used to control the detonation of magnetic field devices, as well as to adjust and control tape-carrying mechanisms.

The aim of the invention is to increase the accuracy of control of the detonation of a magnetic recording apparatus.

The drawing shows a block diagram of the proposed device.

The output of the monitored tape recorder is connected to the input of the bandpass filter 1, which has a central frequency bandwidth equal to the frequency of the test waveform, for example 3, 15 kHz, and a bandwidth equal to the sum of tolerances for the deviation of the speed of the magnetic tape from the nominal value, the tolerance for the frequency deviation of the test waveforms from the terminal to the maximum detonation value. Band-pass filter 1 is connected to the input of threshold element 2, which is made on the basis of a comparator included 10 Schmitt trigger circuit.

The threshold element 2 is connected to a single trigger input 3, to the input line 4 of the delay and the recording input of the nerve register 5. The trigger 3 is connected to the first input of the logic element And 6 by its output, to the second input of which the generator 7 of the reference frequency is connected, and to the output - counting the inputs of the nerve and second counters 8 and 9.

The nerve counter reset input 8 is connected to the output of the delay line 4, the transfer output of the counter 8 is connected to the zero input of the trigger 3, and the output of the counter 8 is connected to the information input of the nerve register 5, the output of which through the digital-to-analog converter 10 and the weighing filter 11 is connected to the same input of the comparator 12. The weighing filter 11 has an amplitude-frequency characteristic that matches the frequency response of the auditory perception of frequency modulation. The other input of the comparator 12 through digital-to-analog converter 13 is connected to the output of the second counter 9 and through the third counter 14 is connected to the information input of the second register 15.

The output of the comparator 12 is connected to the reset input of the second counter 9 and through the fourth counter 16 to the recording input of the second register 15, the output of which is connected to the output bus 17 of the data.

The control device of the detonation of the magnetic device operates as follows.

The test signal pattern, reproduced by the tested magnetic recording apparatus, arrives at the input of the bandpass filter 1, which, due to the imperfection of the tape-conducting mechanism, is subjected to partial modulation. Band-pass filter 1 transmits signals with a frequency which range is not

n) emit bandwidth. The threshold element 2 but the signals of the test siglogram form a sequence of rectangular pulses, which is also subjected to frequency modulation. On the first pulse from the sequence of mono-angular pulses, the trigger 3 is set to one and the reference frequency from the generator 7 begins to flow to the counting input of the first 8 and second 9 counters. By

the front of each rectangular pulse, the first register 5 records information, the station 1 from the first counter 8, and the counter 8 but the same front of the rectangular pulse, but delayed by the line 4

delays are reset. The introduction of the delay line eliminates failures recorded in the register 5 information. In counter 8, the period of the signals of the test waveform is counted, which is subject to frequency modulation, so the first counter 8 counts the different number of pulses of the reference frequency for each period.

Information from the first register 5 is continuously fed to the input of the second digital-to-analog converter 10, which forms at its output a voltage whose amplitude is proportional to the duration of the test signal waveform period. The frequency of the test waveform (3, 16 kHz) is sufficient to transmit without loss of the frequency spectrum from the range of auditory perception of frequency modulation. The pulse frequency of the generator 7 of the reference frequency is chosen such that the resolution of the period duration counter, i.e., the first counter 8, is sufficient. For example, the reference frequency is 75 MHz.

The first register 5 records only those bits of information from the first counter 8, which can change their value from period to period. The output of the digital-to-analog converter 10 produces a voltage modulated in amplitude due to the frequency modulation of the test waveform signals. The weighing filter 11 filters out the frequency range modulating the signals of the test signal, the frequency range of the auditory perception of the frequency modulation and transmits the amplitude-modulated signal to the second input of the comparator 12. At the same time

Q to the first input of the comparator 12 enters a stepwise sawtooth voltage generated by a digital-to-analog converter 13 using codes from the second counter 9 to the input of it. When the voltages to the input of the comparator 12 are equal, a pulse is generated at its output, which resets the second the counter 9 and which is read by the fourth counter 16. These procedures measure the weighted amplitude modulated voltage.

The fourth counter 16 counts the number of measurements taken, and the third counter 14, the counting input of which is connected to the least significant bit of the second counter 9, accumulates the sum of the values of the measured amplitude-modulated voltage. The fourth counter 16 is chosen in such a way that it overflows during the time required to obtain a reliable average value of amplitude modulated voltage, for example ineteen bits corresponds to 2, 16 the number of measurements that can be made in a few seconds with a certain steepness the saw-tooth voltage produced by the digital-to-analog converter 13. The steepness of the step-saw-tooth voltage is given by the second counter 9, which converts the number of and the pulses of the reference frequency into a binary n-bit code, which is fed to the input of a digital-to-analog converter, 13.

The third counter 14, which is not reset with each measurement, accumulates the value of the total number of pulses that arrive at the input of the second counter 9 over the entire measurement cycle, thereby the third counter 14 counts the sum of the instantaneous values of the amplitude modulated voltage. When the fourth counter 16 overflows, a transfer signal appears at its output, which is fed to the input of the second register 15. The latter records information that goes to its information input from the third counter, and records only bits of information older than the sixteenth bit. By recording information older than the sixteenth bit, the sum of the amplitude-modulated voltage values, i.e., the number of measurements, is divided, thereby calculating the average detonation value, which is fed to the data bus 17 as a digital code for further processing or display.

In the case of a drop-out from a test waveform reproduced by the test tape recorder, the threshold element 2 produces a pause, the duration of which exceeds the capacity of the first counter 8. In this

If the counter 8 generates a transfer signal, arriving at the zero input of the trigger 3, which resets and prohibits the AND 6 logic element from passing pulses from the generator 7 of the reference frequency. At the same time, the detonation measurement process stops. When a signal of the test waveform arrives, the measurement process is resumed. This eliminates false positives of the device for controlling the detonation of a magnetic recording apparatus when a signal falls out of a reproducible test waveform, which improves the accuracy of the measurements.

Claims (1)

Invention Formula A device for controlling the detonation of a magnetic recording apparatus, comprising a trigger, the output of which is connected to the first input of an element AND, a delay line, a first counter and a reference frequency generator, characterized in that, in order to improve the accuracy of control of detonation, a band-pass filter is introduced into it, a threshold element the second, third and fourth counters, two registers, a digital-to-analog converter, a weighting filter and a comparator, the input of a band-pass filter connected to the input of the device, and the output through a threshold element - from one the trigger input, the input of the delay line and the recording input of the first register, whose information input is connected to the output of the first counter, the reset input of which is connected to the output of the delay line, the transfer output is connected to the zero input of the trigger, and the count input is connected to the output of the And element, the second input which is connected to the output of the reference frequency generator, the output of the element I is connected to the counting input of the second counter, the output of which through the third counter is connected to the information input of the second register, and through the first digital-analogue the new converter is with the first input of the comparator, the information output of the first register is connected through the second digital-to-analog converter and the weighing filter connected in series to the second input of the comparator whose output is connected to the reset input of the second counter and through the fourth counter is connected to the input of the second register whose information output is connected with the output of the device.