DE3110142C2 - - Google Patents

Description

The invention is based on a video recorder with improved Recording the sound signal according to the preamble of Claim 1. Such a video recorder is described in DE-OS 31 34 737.

The disturbances in the sound signal during playback preferably arise by the one taking place during the inclined track recording Head change. The head change is annoying during image playback not because it occurs during the vertical blanking interval. When the sound signal is played back, however, this head change audible as a disturbing noise because of the head change the sampling of the sound signal modulated onto a carrier briefly interrupted by the band at 50 Hz is. The resulting needle-shaped interference pulses a fundamental frequency of 50 Hz and a large proportion of Harmonics produce a continuous sound Noise.

The invention has for its object a compensation of signal dropouts in the audio signal to create the greatest possible regardless of the cause and type of malfunction in the Sound signal works.

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

It is also known (DE-AS 25 39 059), with an image plate below the color signal band between two FM-modulated Sound carriers to record a pilot signal for elimination of phase errors in the conversion of the color signal can be used. The task by changing heads conditional noise in the audio signal during playback compensate, but is not dealt with there and also unsolved.  

The invention is based on the following knowledge. The said Interference signal in the sampled audio signal cannot be per se separate again from the useful audio signal. The one according to the invention additionally recorded unmodulated pilot carriers delivers however during playback after its demodulation that interference signal that in the sampled demodulated audio signal is available. Therefore, this can be from the pilot carrier obtained interference signal to eliminate the in the sampled Sound signal existing interference signal can be exploited. The Frequency of the recorded modulated sound carrier or several sound carriers in stereo or multilingual television is preferably at the maximum of the head-band frequency response characteristic of the recorder. In practice, this is about lower end of the one occupied by the modulated image carrier Frequency range. Due to this frequency position of the modulated The following advantageous combination effect results from the sound carrier. On the one hand, the modulated frequency lies due to this frequency selection Sound carriers at one point in the entire frequency range, where sensitivity of recording and sensing and thus the signal-to-noise ratio are also maximum. The sound carrier is lying then within the frequency spectrum of the modulated Image carrier. The mentioned frequency position of the sound carrier in lower range of the frequency spectrum of the modulated image carrier but corresponds to high frequency components of the recorded Video signal. According to statistical signal distribution video signals of high frequency occur only per unit of time during about 10% of the respective time unit. By this fact also results in a minimal one  The sound signal interferes with the image.

The invention therefore uses the large bandwidth available advantageous when recording on the helical tracks Recording of the sound signal used. By high frequency Recording the sound signal can be an FM quality reach for the sound. Another advantage is that the longitudinal track previously required for the recording of the sound signal can be omitted. It can then be an additional one Area of the magnetic tape for recording the image signal be used. This can either improve quality improved image recording or reduced tape consumption will. A particularly good use of the magnetic tape can be achieved if according to DE-OS 30 11 635 additionally the previously used synchronous track parallel to Band edge for marking the skewed tracks saved and that needed for head control, the individual inclined tracks Signal with a fixed head from the helical tracks derived using the so-called azimuth angle becomes. This means that a VCR can only be used rotating heads for writing the helical tracks without additional recording heads for longitudinal tracks such as B. for realize the sound recording or the synchronous track. The This frees up the belt area while maintaining the same Image quality and the same tape length increase the playing time by about 16%. That means for a game duration of 4 hours provided an additional cassette Playing time of 40 min.

The sound signal can basically be recorded by AM or FM. The recording is preferably carried out in FM because then fluctuations in amplitude of the recorded Sound carrier largely compensated by a limitation can be. When recording through AM can improve the signal-to-noise ratio additionally in a known manner  signal compression during recording and signal expansion during playback, as z. B. under the Trademark "HIGH COM" is known.

An embodiment of the invention is based on the drawing explained. It shows

Fig. 1, the frequency spectrum for the recording of the individual signals on the helical tracks,

Fig. 2 shows a second example of this,

Fig. 3 is a block diagram for recording and

Fig. 4 is a block diagram for playback.

In Fig. 1, the frequency-reduced quadrature-modulated color carrier F is recorded in the lower frequency range with a frequency of 0.63 MHz. The video signal is recorded by FM of an image carrier. Its static modulation characteristic extends between the frequencies 3.8 and 4.8 MHz, where 3.8 MHz corresponds to the black level and 4.8 MHz to the white level of the video signal. The modulation results in a frequency spectrum of 1.3 to 7.3 MHz. Within this frequency spectrum, two sound carriers 1 a and 1 b , each modulated with an LF sound signal in FM, are recorded at the frequencies 1.7 and 1.9 MHz. The two LF audio signals can represent a stereo signal or an audio signal in different languages. At the frequency of 3.8 MHz corresponding to the black level of the video signal, an unmodulated continuous pilot carrier 3 a of constant frequency is recorded. The frequencies of the two sound carriers 1 a , 2 a are approximately at the maximum 4 of the head-band frequency response characteristic 5 , which is effective in recording the entire signal on the helical tracks.

In Fig. 2 the unmodulated pilot carrier 3 b lies between the two modulated sound carriers 1 b and 2 b . For this purpose, their frequencies are slightly further 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 3 b in the immediate vicinity of the frequency of the modulated sound carriers 1 b and 2 b has the advantage that, in addition to the disturbances caused by the head change, it also eliminates those disturbances which may occur in the sound carrier from the luminance signal Y. By demodulating the pilot carrier 3 b lying close in frequency next to the sound carriers 1 b and 2 b , interference signals in the sound signal based on the luminance signal Y can then be eliminated.

In Fig. 3, the CVBS signal in the circuit 6 is separated by frequency-selective means into the modulated color carrier F and the luminance signal Y. The modulated PAL color carrier F is converted in the frequency converter 7 from its original frequency 4.43 MHz to the frequency 0.63 MHz and fed to the adder 8 . The luminance signal Y is modulated onto an image carrier in the frequency modulator 9 , as a result of which a frequency spectrum of 1.3 to 7.3 MHz according to FIG. 1 is produced. In this frequency spectrum, the frequency ranges around 1.7 and 1.9 MHz are suppressed in the circuit 10 a by two notch filters. In the alternative according to FIG. 2, frequency ranges around 1.6 MHz, 1.8 MHz and 2.0 MHz are suppressed in circuit 10 b . The signal remaining as a result is also fed to the adder 8 . Two sound signals NF 1 and NF 2 are modulated in two frequency modulators 11, 12, two carriers with the frequency of 1.7 and 1.9 MHz or, in the alternative according to FIG. 2, of 1.9 and 2.0 MHz, which also be added to the adder 8 . With an NF frequency band of 15 KHz to be transmitted, 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. To avoid disturbances in the Y signal by the two sound carrier and the 1.8-MHz pilot carrier are in the circuit 10 a (10 b), the frequencies of the two sound carrier having a bandwidth of ± 65 KHz and the unmodulated pilot carrier of Figure 1, 8 MHz suppressed by the notch filters mentioned. The unmodulated carrier of 3.8 MHz or 1.8 MHz is generated in the generator 13 and is also fed to the adder 8 . The output of the adder 8 contains the signals shown in Fig. 1 and is supplied to the magnetic head 14 for recording on a magnetic tape. This signal mixture shown in Fig. 1 or 2 is then recorded on the inclined tracks of a magnetic tape.

In Fig. 4, the signal mixture sampled by the head 14 according to Fig. 1 or 2 is amplified in the amplifier 15 and split with the filters 16, 17 a , 17 b into the modulated color carrier F and the modulated image carrier Y _FM . The color carrier F is converted back to the frequency of 4.43 MHz in the frequency converter 18 and fed to the adder 19 . In the filter 17 a or 17 b frequency ranges at 1.7 and 1.9 MHz or 1.6; 1.8; 2.0 MHz suppressed by notch filters to avoid disturbing the sound carriers during image playback. The resulting slight decrease in sharpness is practically imperceptible. The luminance signal Y is obtained in the frequency demodulator 20 and supplied to the adder 19 .

The two modulated sound carriers are selectively separated from the signal mixture according to FIG. 1 by means of narrow-band filters 21, 22 and supplied to appropriately tuned frequency demodulators 23, 24 . The demodulators deliver a useful signal U _N for the two audio signals NF 1 and NF 2 . However, due to the head change at 50 Hz, they also deliver an interference signal U _S which would be clearly audible when the sound signals were reproduced. With the narrow-band filter 25 , the unmodulated pilot carrier of 3.8 MHz or 1.8 MHz is separated out and likewise fed to a frequency demodulator 26 tuned to this frequency. Because of the lack of modulation, the demodulator 26 does not deliver a signal per se. However, it is modulated by the interference signal in the same way as the recorded sound carriers 1 and 2 , because it is subject to exactly the same influences as the two modulated sound carriers with regard to the head change. At the output of the demodulator 26 there is therefore the interference signal U _S alone. This interference signal is subtracted from the sum signal U _N + U _S in the subtraction stages 27 and 28 . This results in the audio signals NF 1 and NF 2 at the outputs of the subtracting stages 27, 28 , which now only contain the useful signal U _N and are free from the interference signal U _S. Since the pilot carrier of 3.8 MHz lies at the static frequency of the image carrier for the video signal value black, it does not cause any disturbances in the reproduced image. A notch filter is also not necessary for him, while a pilot carrier of 1.8 MHz must be suppressed by notch filters. The pilot carrier of 1.8 MHz has the advantage over the pilot carrier of 3.8 MHz, which only eliminates head change interference, that it also detects any interference from the Y channel in the audio channels lying between the two audio carriers, which also occurs in the Subtracting stages 27, 28 are eliminated.

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

Claims (9)

1. Video recorder with improved recording of the audio signal, in which an image carrier modulated with the video signal in FM and an audio carrier modulated with the LF audio signal are recorded within the frequency spectrum of the image carrier along inclined tracks of the magnetic tape and during playback means for compensating for disturbances in the audio signal are provided, characterized in that a non-modulated pilot carrier ( 3 ) offset from the frequency of the sound carrier ( 1, 2 ) along the inclined tracks is also recorded within the frequency spectrum of the image carrier and an interference signal (Us) obtained by demodulating the pilot carrier ( 3 ) is subtracted from the sound signal obtained by demodulating the sound carrier ( 1, 2 ). 2. Recorder according to claim 1, characterized in that the frequency of the sound carrier ( 1, 2 ) is approximately at the maximum ( 4 ) of the head / band frequency response characteristic ( 5 ). 3. Recorder according to claim 1, characterized in that the frequency of the pilot carrier ( 3 ) is close to the frequency of the sound carrier ( 1, 2 ), but outside of its frequency spectrum. 4. Recorder according to claim 3, characterized in that in the case of two recorded sound carriers ( 1, 2 ) the frequency of the pilot carrier ( 3 ) lies between the frequencies of the two sound carriers ( 1, 2 ). 5. Recorder according to claim 1, characterized in that the frequency of the pilot carrier ( 3 ) has a value which corresponds to a periodically recurring value of the video signal (black or white) in the modulation characteristic of the image carrier. 6. Recorder according to claim 1, characterized in that the amplitude of the sound carrier ( 1, 2 ) and / or the pilot carrier ( 3 ) is in the order of 10% of 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 the pilot carrier ( 3 ) corresponding frequency range is suppressed with a filter ( 10 ). 8. Recorder according to claim 1, characterized in that in Way of the sound signal to improve the signal-to-noise ratio Circuit for compression during recording and for expansion during playback. 9. Recorder according to claim 1, characterized in that at Avoiding a synchronous track parallel to the belt edge Obtaining a synchronization signal marking the helical tracks from the helical tracks the helical tracks over the extend the entire width of the magnetic tape.