SU1012332A1 - Method of supperessing pulse interferences in reproducing previously recorded signalogram - Google Patents

Abstract

SPSKHYUB surge suppression when playing back a previously recorded waveform, includes reproduction of stereo signals, their arithmetic transformation, forming control pulses on the basis preobrazovanHbtx signals Derzhko vosprshave e GOVERNMENTAL stereo signals in time and n (i pressure imyulsnyh-interference via control pulses, wherein that, in order to improve the accuracy of suppressing the multiplexed mark during the restoration of the sound recordings, the formation of a signal passage nickel is formed, in which, after ar before the formation of control pulses, the pulse & noise pulses the interference with the spectrum in one of the bands of the working frequency range, and after the selection of the pulse noise the intermediate recording of the stereo signals, while stereo-signals are used as the source reproduced from the orvoginal of the signal source, repeat the cycles until the moment of makimalak-g 9 of the decrease of the pulse points. c (L using intermediate pre-recorded stereo signals on the high end, pulsed interference with the spectrum in another band of the working range is separated.

Description

The invention relates to instrumentation 1 and can be used mainly in the restoration of old or worn recordings, in particular phonograms. The known method of noise suppression, which can be implemented during reproduction, as well as during the restoration of the signal recording, is recorded mechanically by C lH and 2.. This method involves, in addition to using the reception of arithmetic conversion of the reproduced signals, also the formation of a number of control pulses, which ultimately RELEASES or compensate for signals with a noise component, or to suppress such signals at a level of minimum audibility. However, this method allows the effect of modulating a useful signal by a noise signal at certain intervals to occur, which leads to a decrease in the intelligibility of the waveform. The closest to the proposed method is the suppression of impulse noise during reproduction of a previously recorded signal, including stereo signal multiplication, arithmetic conversion, generation of control pulses based on the converted signals, delayed reproduction of stereo signals using control signals impulses 3}. But despite all the positive qualities, this method does not allow X to carry out their suppression with a sufficiently high degree of accuracy pully interference, precisely during the restoration of the sound recordings. J The aim of the invention is to improve the accuracy of the suppression of impulse noise during the distribution of the waveforms. This goal is achieved by the fact that, when implementing a method for suppressing impulse noise during reproduction of a previously recorded waveform, including playing stereo signals, arithmetic conversion, generating control pulses based on the converted signals, delaying the reproduced stereo signals in time, and suppressing impulse noise using control pulses, t the formation of a cycle of passing signals, in which, after arithmetic conversion and re-formation by control pulses are carried out with the spectrum in one of the bands of the working frequency range, and after the separation of the pulsed noises - an intermediate recording of stereo signals, in this case. stereo signals reproduced from the original source of the waveform are used as source signals, cycles are repeated until the pulse interference is minimized using an intermediate recording of the stereo signals of the previous cycle and pulse interference with the spectrum in another band of the working frequency range is selected. Fig. 1 shows an oscillogram from Pnalov, which is obtained at the output of a two-channel pickup or a two-track magnetic head (depending on the type of carrier); in fig. 2 is the same but after an arithmetic transformation operation; in fig. 3 — Ospilogram obtained after isolating impulse noise whose spectrum is in the high-frequency region; in fig. 4 shows control pulses formed from signals whose oscillogram is shown in FIG. 3; in fig. 5 is a block diagram of a device implementing the proposed method. . FIG. 1, 2 and 3, the following notation; useful low-frequency signal b - pulse signal of medium duration; c - pulse signal of low short-duration interference, the threshold designation Unop i at which pulse interference is suppressed. The structure diagram in FIG. 5 is constructed in such a way that either a two-channel pickup 1 or a two-channel element with any output electric signal is installed at the input, for example, a two-track magnetic magnetic circuit. In the following, this position will be understood as the reproducing element 1 and it is connected to the magnetic recording apparatus 2. In such a device, the signal is processed using a delay line 3 connected to the impulse noise suppression unit 4 together with the control unit 5. In turn, to the input the control unit & 5 are connected in series to connect the arithmetic transform of epi 6 and frequency equalizer 7, which is simultaneously with the indicator input 8. Unit 4 is loaded on the second magnetic recording device 9, and reproducing element 1 - to the switches 10. Let us consider the case when using a two-channel pickup as a reproducing element, and not carrying a carrier 1, not shown) is a restoration of the phonogram of the phonogram quality. During needle movement (not shown) of the pickup, it receives horizontal and vertical movements within the groove of the carrier. From the horizontal displacements, mainly useful signals are generated, which at both outputs of the pickup (if coherent signals are recorded) are in the same phase. From vertical movements, mainly, pulsed components are formed, pomesh X, which are in a prostate phase and occur when the needle passes through various kinds of damage (cracks,; scratches, hollows, etc.). During the Signal conversion process, they are subtracted i.e. the subtraction of stereo signals, using converter 6, as a result of which the useful oo signals are compressed and the pulse noise is amplified. However, with some temporal and spectral differences in the signals of the field: His attenuation cannot be reached, which can lead to unnecessary loss of useful information (Fig. 2). Therefore ; it is very important to increase the ratio of the levels of impulse noise to the level of the useful signal before the formation of the pulses controlling the process, suppression. Such an increase is achieved by cyclically repeating the entire process, and each time before forming .ravlating pulses in the coil by changing the bandwidth of the pulses: of a certain type of interference (for example, short-duration interference pulses), oolabl signals and interference disturbances of other PCRs, whose spectrum does not fall in the selected descent strip u low and medium sound frequencies, as well as noise pulses of medium and longer duration, as shown in Fig. 3). The selection of impulse noise is controlled visually by means of an indicator 8. Then control pulses are formed The syllables (Fig. 4) suppress the impulses of these interferences into the soundtrack & my phonogram. The processed signals in this way are recorded using a magnetic recorder 9 and then the processed signal is reproduced using apparatus 2 and the cycle repeats again with the release of impulse noise, but of a different kind, for example, noise longer than xi in the previous case. This interference is also suppressed after the end of the cycle, and a new recording of the processed signals is obtained. For each cycle, the optimal values of the pulse shaping threshold in the time delay of the stereo signals are selected in such a way as to completely suppress the impulse noise of this type. According to the operation of the circuit shown in FIG. 5, the signals from the switch -. Leu 10 simultaneously hit both the transducer 6 and the delay line 3. But after arithmetic transforming, neither the corrector 7 emits pulsed noise, the spectrum of which is in the high frequency region of this operating range, and with the help of the control unit 5, control pulses are generated , with the help of which the suppression of the impulse noise occurs. Re-recording of this method will allow to restore the sound recordings, in particular, the phonogram with the speeches of famous people and the most valuable musical works in a relatively inexpensive way.

Claims (1)

METHOD FOR SUPPRESSING PULSE INTERFERENCE WHEN PLAYING — DENISION OF AN EARLY RECORDED SIGNALOGRAM, including the reproduction of stereo signals, their arithmetic conversion, the formation of control pulses based on the converted signals, the delay of reproduced stereo signals in time and the suppression of impulse noise using control pulses, which In order to improve the accuracy of suppression of impulse noise during restoration of signalograms, a signal propagation cycle is formed, in which after a ifmeticheokogo conversion and prior to forming control pulses performed selection pulse, interference with the spectrum in a band of operating frequency band, and after discharge. pulsed interference - an intermediate recording of stereo signals, in which case stereo signals reproduced from the original of the hawker signalogram are used as the source signals, cycles are repeated until the maximum reduction of pulsed noise using the intermediate recording of stereo signals of the previous cycle and impulse noise with a spectrum in a different band of the operating frequency range is isolated. DOF 00 to