SU1056262A1 - Method of multichannel reproducing of pulse-frequency modulated signal from magnetic medium - Google Patents

Abstract

THE METHOD OF MULTI-CHANNEL REPRODUCTION OF THE FREQUENCY-PULSE-MODULATED SIGNALS FROM A MAGNETIC MEDIA, counters in amplifying and shaping signals, then filtering them and switching the received signals, so that, in order to improve the accuracy of reproduction, they will change their results and filter them and switch the received signals, so that, in order to increase the accuracy of reproduction, they will be less likely to change, if they will change, to improve the accuracy of reproduction. , a signal is generated of the first code corresponding to the rotation speed of the driving motor of the magnetic carrier transport mechanism in the reference channel of the sig Ail amplified and generated pulse sequence KJ are divided by the pilots, the code of the registration rate magnitude code and the signal of the change of the carrier frequency range of the modulated signals, convert the pilot frequency values into the second code signal, then the registration speed magnitude code values are stored and compared in series with the values of the first and second codes and by the obtained result of the comparison change the speed of movement of the magnetic carrier and the coefficient (the transfer factor is reproducible x signals, and when the C signal appears, the change in the carrier frequency range of the modulated signals changes the value of the filtering band of the information signals.

Description

The invention relates to instrumentation, in particular, to methods for multiple-channel reproduction of frequency-pulse-modulated (PFM) signals from a magnetic carrier. There is a known method of magnetic recording playback, based on modulation and demodulation of the signal carrier. In order to increase the noise immunity of the recording / reproduction channels of magnetic recording devices. During playback, one of the parameters of the demodulated signal is dynamically controlled depending on the characteristics of the output signal p. . One embodiment of this method is a playback device in which the operations closest to the proposed method are performed, namely: the product, amplification and generation of the signal, its filtering and switching of the filter result. By improving the noise immunity of the reproduction channel, these operations, however, do not provide demodulation of PFM signals reproduced from magnetic media, which were recorded at varying speeds of movement & amphibious media. The purpose of the invention is to increase the reproducibility of the measurements when measuring the speed of movement of the carrier and to increase the efficiency of its use. This goal is achieved by the fact that, according to the method of multichannel reproduction of frequency-pulse-modulated signals from a magnetic carrier, consisting in amplifying and shaping signals, then filtering and switching received signals, form a signal of the first code corresponding to the rotation speed of the driving motor of the magnetic carrier transport mechanism in the reference the pilot signal is extracted from the signals of the amplified and formed pulse sequence; The registration numbers and the signal of the change of the carrier frequency range of the r-dadulized signals convert the pilot signal frequency values into a second code signal, then the values of the code of the registration speed value are stored and. compare the values of the first and second codes in succession and, according to the result, compare the magnetic carrier speed and transmission ratio of the reproduced signals, and when a signal appears indicating that the carrier frequency changes, the modulated signals change the value of the filtering band of information signals. Pa figs. 1 shows the structural scheme of one of the options for implementation. of the proposed method} in FIG. 2-time diagrams of the device. The device contains a leading motor, a gatel 1 and a tachometer 2 located on its shaft, which belong to the magnetic carrier transportation mechanism 3. In the device, the first input bus 4 through the first reproduction amplifier 5 and the first impulse generator 6 are connected in parallel to detector 7 of the registration rate value code and detector 8 to indicate the change in frequency of the modulated carrier oscillations. The second output of the first shaper b pulses connected to the meter 9 frequency of the pilot signal. Blocks 5.-9 constitute the reference channel 10. The outputs of the tachometer 2, detector | Paragraph 7 of the registration rate value code, the detector 8 of the change sign of the frequency of the modulated carrier waves and the pilot frequency meter 9, respectively, are connected to the first second, third and fourth inputs of the comparator unit 11 whose first input coincides with the driving speed control signal bus 12 and the second output is with the second (control input of the playback amplifier 5. The device also comprises a second input bus 13, which, through the second playback amplifier 14, the second driver 15 impulses The co-drivers are connected in parallel to the first / iy and second standby multivibrators 16 and 17. The number of pending multivibrators in the device corresponds to the Number of signal acquisition ranges. The outputs of the waiting multivibrators 16 and 17 are connected via the first and second filters 18 and 19 of the lower frequencies to the first and second inputs. The number of low-pass filters, as well as the number of signal inputs of the switch 20, is identical to the number of waiting multivibrators and is determined by the number of filtering bands of the information signal. Blocks 14-20 constitute the information channel 21. The output of the switch 20 coincides with the output bus 22 of the device. FIG. 1 shows one information channel 21, however, in the device, their number may be large. In the proposed device, the second I control input of the second playback amplifier 14 is connected, with the second (control) input of the first playback amplifier 5, and the third input of the comparison unit 11 connected to the control input of the switch 20.

The spacing is as follows.

In the initial period of time block

11 comparisons on its output bus

12 forms a control signal of a constant value, in accordance with

With which the driving motor 1 of the magnetic carrier transporting mechanism 3 obtains a stable rotational speed measured by such a sensor 2. The magnetic carrier acquires a constant speed of movement, the value of which is maintained by the control system (not shown, And the playback time of reproducible playback heads (not shown) of signals depends on magnitude of the speed of movement of the magnetic carrier, and in order to comply with the linear mode of operation of the amplifiers 5 and 14 of the output, the device provides feedback to the second The output of the control unit 11, on which the signal controlling the transmission coefficient is generated, is applied to the second (control) inputs of the playback amplifiers 5 and 14. The signal received from the input bus 4 on the playback amplifier 5 and the pulse former 6 is amplified and shaped in two directions. The amplified signal has the form, for example, of a pulse-width modulated sequence, in which positive responses represent a pilot signal, and the temporal position of the negative responses carries information about X codes of the magnitude of the registration rate and with a sign of changing the range of & on the frequency of the carrier modulated signals. The detectors 7 and 8 at their outputs form, respectively, the code of the magnitude of the registration rate and the indication of the change in the frequency range of the carrier modulated signals. These signals are sent to processing comparison block 11, in particular, block 11 memorizes the next value of the registration rate quantity code, which becomes a program value for the magnetic carrier speed control system. Simultaneously, from the second output of the pulse generator 6, a pilot signal is transmitted to the frequency meter 9, which characterizes the average and instantaneous values of the velocity of the magnetic carrier during registration. The output signal from the frequency meter 9, expressed as a code, is fed to the third input of the comparator unit 11, and the fourth input of this unit continuously receives the output signal from the tachometer 2, which characterizes the speed of rotation of the driving motor 1.

Thus, in block 11, the comparison of three of the four input signals are: a constant (program) code value of the registration rate, variable code values of the average and instantaneous speed of the magnetic carrier during registration, and variable code values of the rotation speed of the driving motor 1. Block 11 code comparisons after receiving the program code value

is transferred to the Formation, Control, and Control of a variable signal. The magnetic carrier changes the magnitude of its movement speed according to the law of the control signal. The control signal contains two components. The first component passes the average speed value.

rotation drive motor and provides a stable and wide range, speed control system. The second component transmits the value of the instantaneous speed of movement of the magnetic carrier during registration and provides a reduction in the transient process time and the accuracy of the control system.

The response to the influence of the control signal is a reaction to the cyi-jMy effects from the first and second components of the control signal, and therefore the acceleration (deceleration) of the driving motor when subjected to a control signal of a similar structure occurs smoothly and with a high degree of measurement registrations on areas of driving (braking) of the recording mechanism for transporting magnetic media. The transient mode ends on condition that the codes contained in the three output signals of the comparator block 11 are equal. The device enters the established mode of processing of the PWM signals in the information channels 21, in which the value of the speed of movement of the magnetic carrier is constant and equal to the speed of recording the PWM signals. At the same time, the comparator unit 11 generates a signal controlling the transmission coefficient of the reproduction amplifiers 5 and 14 in accordance with the instantaneous speed of movement of the magnetic carrier. As a result, in both the transitional and the steady-state modes, the linearity of the reproduced signals is maintained.

The fourth input signal of comparator unit 11 is a sign of a change in the frequency range of the carrier modulated signals, when it appears, the comparator unit 11 generates a control signal containing information about the value of the filtering band of information signals. The control signal connects to one of the inputs of the switch 20 a frequency-pulse demodulator, CONSISTING from waiting 1 of its multivibrator 16 (17) and Filter (18) 19 low frequencies and the corresponding reproducible | at the frequency range: information signal. As a result, an information signal is extracted on the output bus 22 of the device, which was recorded at a variable speed of movement of the magnetic carrier. With the new value of the reproduced code of the registration speed value, the device repeats the transient mode of operation until the codes become equal as a result of controlling the speed of movement of the magnetic carrier. The appearance of a change in the frequency range of the carrier modulated signals causes switching of the inputs of the switch 20 and to the output bus 22

An information signal is received from the state system corresponding to the new value of the registration rate.

The proposed method, in comparison with the known one, allows one to obtain the result of demodulation of the PFM sigals recorded with the variable speed of the magnetic carrier.

An experimental test allowed us to obtain reproduction and demodulation of multichannel PWM signals on a tape drive mechanism with a continuously controlled speed of movement of the magnetic carrier. In this case, the mode of receiving the signal was checked, controlling the speed of movement of the magnetic carrier, depending on the code value of the registration rate and the frequency of the pilot signal. On. the output of the device received the exact values of the information signals, demodulation from the PFM sequences.

The use of the proposed device in reproducing real signals of information on rapidly changing processes made it possible to obtain also a saving in the amount of magnetic carrier by a factor of two as compared with the use of the known device.

Claims (1)

METHOD OF MULTI-CHANNEL PLAY OF FREQUENCY-PULSE-MODULATED SIGNALS FROM A MAGNETIC CARRIER, which consists in amplifying and generating signals, their subsequent filtering and switching of the received signals, characterized in that, in order to increase the fidelity of reproduction with changes in the speed of the carrier and increase its efficiency form a signal of the first code corresponding to the speed] of rotation of the driving engine of the mechanism for transporting the magnetic medium in the reference channel from the signals The amplified and generated pulse sequence is used to extract the pilot signal, the signal of the registration speed magnitude code and the signal indicating the change in the carrier frequency range of the modulated signals, convert the values of the pilot signal frequency to the second code signal, then the values of the registration speed magnitude code are stored and compared sequentially with the values of the first and second codes and for the comparison _with the results obtained tattoo 1S change speed movement of the magnetic carrier and the transmission ratio of the reproduced signals, and when a signal of a sign of changing the carrier frequency range of the modulated signals appears, the value of the filtering band of the information signals is changed. P Z3ZWT ^{,, _} ns>