DE3110142A1 - Video recorder with improved audio signal recording - Google Patents

Abstract

In a video recorder with helical track recording, the audio signal (AF) is also recorded in the helical tracks by modulating a subcarrier (1, 2) within the frequency spectrum of the modulated video carrier. In addition, an unmodulated subcarrier (3) is recorded. During the replay, this latter carrier supplies an interference signal (Us) due to the head switching. This interference signal is subtracted from the audio signal in subtracting stages (27, 28). This eliminates the interference signal in the audio which normally occurs due to the head switching. <IMAGE>

Description

Video recorder with improved recording of the audio signal

In video recorders, it is known that the video signal by frequency modulation of an image carrier on so-called oblique tracks that are at an angle from approx. 60 diagonally to the longitudinal direction of the belt. It is preferred one field is recorded in each case along such a helical track. recording and scanning are carried out with two heads, each alternating the helical tracks sample, with such devices the audio signal is on a parallel to the tape edge running longitudinal track with a width of about 1 mm with a fixed head recorded and scanned. For recording and sampling the audio signal is therefore the longitudinal speed of the belt and not the much higher relative speed crucial between head and tape on the diagonal tracks. The longitudinal speed of the tape is in practice to increase the total playing time of a tape has been reduced to values on the order of 2 cmls. This low relative speed between the tape and the tape head has a disadvantage Influence on the quality of the recorded audio signal. A hi-fi quality can be achieved practically no longer achieve this low relative speed. The recorded The audio signal only has a bandwidth of around 70 Hz to 7-10 KHz. Because of the low Width of the longitudinal track also results in a relatively poor signal-to-noise ratio. This is used when recording two audio signals for stereo playback through the then necessary halving of the width of the longitudinal track even worse.

It is conceivable per se, similar to the audio signal, as is the case with the video disk to be recorded together with the image carrier on the oblique tracks. Such a solution has not yet been successfully implemented in practice. On the one hand the available frequency range is already fully used.

The range of about 0-1.3 MHz is lowered in frequency from that quadrature modulated color subcarrier and the rest of the frequency range through the frequency spectrum of the modulated image carrier. A recording of a phonogram in the still existing narrow frequency gap between the modulated color carrier and the frequency spectrum of the image carrier is due to the necessary steep filter edges for the color carrier and the image carrier because of the phase and group delay errors that occur practically impossible.

On the other hand, when the audio signal is recorded on the Inclined tracks during playback a considerable disturbance due to the head change. At. The head change does not interfere with the image reproduction because it occurs during the vertical blanking interval he follows. When the audio signal is played back, however, this head change is seen as a disturbing one Noise audible because the head change causes the scanning of e.g. one wearer modulated audio signal from the tape is briefly interrupted at 50 Hz. The resulting needle-shaped interference pulses with a base frequency of 50 Hz and a large proportion of harmonics produce a continuous sound reproduction Background noise.

The invention is based on the object of recording the audio signal on the helical tracks with good quality and without disturbance from the head change enable.

This object is achieved by the invention described in claim 1 solved. Advantageous further developments of the invention are described in the subclaims.

The invention is based on the following knowledge. The said interfering signal in the sampled audio signal cannot be taken from the useful audio signal again separate. The unmodulated pilot carrier additionally recorded according to the invention however, during playback after its demodulation, delivers the interference signal present in the sampled demodulated audio signal. Therefore this can be done the interfering signal obtained from the pilot carrier to eliminate the audio signal being sampled existing interfering signal can be exploited. The frequency of the recorded modulated Sound carrier or several sound carriers in stereo or multi-language television preferably at the maximum of the head # tape frequency response curve of the recorder. These is in practice approximately at the lower end of that occupied by the modulated image carrier Frequency range. This frequency position of the modulated sound carrier results the following advantageous combination effect. On the one hand lies through this choice of frequency the modulated sound carrier at one point in the entire frequency range where sensitivity of recording and scanning and thus also the signal-to-noise ratio are maximum. The sound carrier then lies within the frequency spectrum of the modulated picture carrier. the named frequency position of the sound carrier in the lower range of the frequency spectrum of the modulated image carrier corresponds to high frequency components of the recorded Video signal. Video signals occur according to statistical signal distribution per unit of time high frequency only during about 10 5 'of the respective time unit. Through this So there is also a minimal fact Disturbance of the picture display by the sound signal.

In the invention, the large available bandwidth in the Recording on the helical tracks is advantageously used for recording the audio signal. FM quality can be achieved by high-frequency recording of the audio signal for the sound. Another advantage is that the previously required Longitudinal track for recording the audio signal can be omitted. It can then be an additional Area of the magnetic tape can be used for recording the image signal. This can either improve the quality of the image recording or reduce tape consumption be reduced. A particularly good utilization of the magnetic tape can be achieved if, according to DE-OS 30 11 635, the previously used synchronous track in parallel to the edge of the tape to mark the inclined tracks and that for head regulation needed to indicate the individual helical tracks with a fixed signal Head derived from the helical tracks using the so-called azimuth angle will. This means that a video recorder can only be used with rotating heads for writing of the helical tracks without additional recording heads for longitudinal tracks such as for to realize the sound recording or the synchronous track. The one that becomes free as a result Tape area enables an increase with the same image quality and the same tape length the playing time at around 16 5 '. That means with one for a playing time of 4 hours provided cassette an additional playing time of 40 minutes.

The recording of the audio signal can basically be done by AM or FM take place. The recording is preferably made in FM because amplitude fluctuations then occur of the recorded sound carrier largely offset by a limitation can be. When recording by AM can improve the signal-to-noise ratio additionally in a known manner signal compression during recording and signal expansion can be performed on reproduction, for example, as described under the trademark "HIGH COM2 'is known.

An embodiment of the invention is explained with reference to the drawing. FIG. 1 shows the frequency spectrum for recording the individual signals on the helical tracks, FIG. 2 a second example of this, FIG. 3 a block diagram for recording and Figure 4 is a block diagram for playback.

In FIG. 1, the frequency range is reduced in the lower frequency range quadrature modulated color carrier F recorded at a frequency of 0.63 MHz. The video signal is recorded by FM of a picture carrier. Its static modulation characteristic extends between the frequencies 3.8 and 4.8 MHz, with 3.8 MHz being the black level and 4.8 MHz corresponds to the white level of the video signal. The modulation results a frequency spectrum from 1.3 to 7.3 MHz within this frequency spectrum are two at the frequencies 1.7 and 1.9 MHz, each modulated with an LF tone signal in FM Sound carriers ia and ib recorded. The two audio signals can be a stereo signal or display a sound signal in different languages. With the black level The frequency of 3.8 MHz corresponding to the video signal is an unmodulated continuous Pilot carrier 3a recorded constant frequency. The frequencies of the two sound carriers 1 a, 2 a are approximately at the maximum 4 of the Xopf band frequency response characteristic curve 5, which is at recording of the entire signal on the helical tracks is effective.

In Figure 2, the unmodulated pilot carrier 3b lies between the two modulated sound carriers lb and 2b. Their frequencies are a little further for this purpose apart than in Fig. 1, namely at 1.6 and 2§0 MHz. The frequency of the Pilot carrier is 1.8 MHz. This frequency position of the pilot carrier 3b in the immediate vicinity the frequency of the modulated sound carrier lb and 2b has the advantage that it besides the Disturbances caused by the change of head also eliminated disturbances resulting from the Luminance signal Y can occur in the sound carrier. By demodulating the Frequency close to the sound carriers lb and 2b lying pilot carrier 3b can then Interfering signals in the sound signal due to the luminance signal Y can be eliminated.

In Figure 3, the composite signal in the circuit 6 is frequency-selective Means in the modulated color carrier F and the luminance signal Y are separated. Of the modulated PAL color carrier F is in the frequency converter 7 from its original frequency 4.43 MHz converted to the frequency 0.63 MHz and fed to the adder 8. That Luminance signal Y is modulated onto an image carrier in the frequency modulator 9, whereby a frequency spectrum of 1.3 to 7.3 MHz according to FIG. 1 is produced. In this Frequency spectrum are the frequency ranges in the circuit 10a by two notch filters suppressed by 1.7 and 1.9 MHz. In the alternative according to Figure 2 are in the Circuit lOb suppressed frequency ranges around 1.6 MHz, 1.8 MHz and 2.0 MHz. That The remaining signal is also fed to the adder 8. Two beeps NF1 and NF2 are two carriers with the frequency in two frequency modulators 11, 12 of 1.7 and 1.9 MHz or, in the case of the alternative according to Figure 2, of 1.9 and 2.0 MHz, which are also fed to the adder 8. With an LF frequency band to be transmitted of 15 KHz, an FM hub of + 50 KHz is selected, which results in modulation bandwidths of 1.7 (1.6) or 1.9 (2.0) MHz + 65 KHz result. To avoid disruptions in the Y signal through the two sound carriers and the 1.8 MHz pilot carrier are in the Circuit 10a (iOb) the frequencies of the two sound carriers with a bandwidth of 65 KHz and the unmodulated pilot carrier of 1.8 MHz through the mentioned notch filter suppressed. In the generator 13 becomes the unmodulated carrier of 3.8 MHz or 1.8 MHz generated and also fed to the adder 8. The output signal the adder 8 contains the signals shown in Figure 1 and is the magnetic head 14 supplied for recording on a magnetic tape. This shown in Figure 1 or 2 The composite signal is then recorded on the helical tracks of a magnetic tape.

In FIG. 4, the composite signal scanned by the head 14 is shown in FIG 1 or 2 amplified in the amplifier 15 and with the filters 16,17a, 17b in the modulated Split color carrier F and the modulated image carrier YFM. The color carrier F becomes in the frequency converter 18 again converted to the frequency of 4.43 MHz and the Adding stage 19 supplied. In the filter 17a or 17b, frequency ranges are at 1.7 and 1.9 MHz or 1.6; 1.8; 2.0 MHz suppressed by notch filters to avoid interference to avoid the sound carrier when reproducing images. The inherent part of it slight reduction in image sharpness is practically imperceptible. By doing Frequency demodulator 20, the luminance signal Y is obtained and the adder 19 supplied.

The two modulated sound carriers are made with narrow-band filters 21, 22 selectively separated from the composite signal according to FIG. 1 and correspondingly matched frequency demodulators 23,24 supplied. The demodulators deliver for the two audio signals NF1 and NF2 a useful signal UN. But they also deliver due to of the head change with 50 Hz an interfering signal Us, which occurs during the reproduction of the audio signals would be clearly audible. With the narrow-band filter 25, the unmodulated pilot carrier from 3.8 MHz or 1.8 MHz and also one tuned to this frequency Frequency demodulator 26 supplied. The demodulator 26 delivers because of the missing Modulation itself is not a signal. But it is in the same way due to the interference signal Modulated way like the recorded phonograms 1 and 2, because he is subject to exactly the same influences with regard to the head change as the both modulated sound carriers. The interference signal is therefore present at the output of the demodulator 26 Us alone. This interference signal is in the subtraction stages 27 and 28 from the sum signal UN + Us subtracted. This results in 27, 28 at the outputs of the subtraction stages the audio signals NFI and NF2, which now only contain the useful signal UN and from the interference signal Us are exempt. Since the pilot carrier of 3.8 MHz in the static Frequency of the video carrier for the video signal value is black, it does not have any effect Disturbances in the displayed picture. No notch filter is necessary for him while a pilot carrier of 1.8 MHz must be suppressed by a notch filter. The pilot carrier of 1.8 MHz has compared to the pilot carrier of 3.8 MHz, which only has head change interference eliminates the advantage that it is also lying between the two sound carriers detects any interference from the Y channel in the audio channels, which are also included in the subtraction stages 27, 28 are eliminated.

By using an additional compander system, such as HIGH-COM, with an amplitude modulation the sound carrier can have a similar quality as with FM can be achieved without a compander system. One advantage is that the said Notch filters can be made narrower. This in turn would be beneficial for the image sharpness given by the signal Y.

Claims (9)

Patent claims video recorder with improved recording of the Sound signal in which a picture carrier modulated with the video signal in FM passes along Inclined tracks of the magnetic tape and an additional audio signal are recorded, characterized in that a sound carrier (1,2) modulated with the LF sound signal and a non-modulated pilot carrier (3) that is offset in frequency recorded along the helical tracks within the frequency spectrum of the video carrier and that an interference signal obtained by demodulation of the pilot carrier (3) (U5) subtracted from the audio signal obtained by demodulating the audio carrier (1,2) will. 2. Recorder according to claim 1, characterized in that the frequency of the sound carrier (1,2) approximately at the maximum (4) of the head / tape frequency response curve (5) lies. 3. Recorder according to claim 1, characterized in that the frequency of the pilot carrier (3) close to the frequency of the audio carrier (1,2) #, but outside whose frequency spectrum lies. 4. Recorder according to claim 3, characterized in that at two recorded sound carriers (1,2) the frequency of the pilot carrier (3) between the Frequencies of the two sound carriers (1,2) lies. 5. Recorder according to claim 1, characterized in that the frequency of the pilot carrier (3) has a value that corresponds to the modulation characteristic of the image carrier corresponds to a periodically recurring value of the video signal (black or white). 6. Recorder according to claim 1, characterized in that the amplitude of the sound carrier (1,2) and / or the pilot carrier (3) in the order of 10 96 the amplitude of the image carrier. 7. Recorder according to claim 1, characterized in that in the frequency spectrum of the recorded image carrier of the frequency spectrum of the sound carrier (1,2) and / or of the pilot carrier (3) corresponding frequency range is suppressed with a filter (10) is. 8. Recorder according to claim 1, characterized in that in the way of the Sound signal to improve the signal-to-noise ratio a circuit for compression recording and expansion during playback. 9. Recorder according to claim 1, characterized in that if avoided a synchronous track parallel to the tape edge by obtaining one of the helical tracks marking synchronizing signal from the helical tracks the helical tracks are on the extend the entire width of the magnetic tape.