WO1991017628A1

WO1991017628A1 - Video recorder with improved sound recording

Info

Publication number: WO1991017628A1
Application number: PCT/EP1991/000832
Authority: WO
Inventors: Hans-Jürgen Kluth
Original assignee: Deutsche Thomson-Brandt Gmbh
Priority date: 1990-05-09
Filing date: 1991-05-02
Publication date: 1991-11-14
Also published as: AU7765491A; JPH05506760A; DE4014832A1; EP0527795A1; FI925036A0; FI925036A

Abstract

A NICAM sound carrier is transmitted which is modulated with digital sound signals. The purpose is so to construct a VHS video recorder that this sound carrier can be recorded in addition to the other signals without adversely affecting the quality. The NICAM sound carrier is therefore recorded in a deeper layer (S2) with second magnetic heads (K2) in frequency multiplex with EM sound carriers (T1, T2) at lower frequency. Usable especially for an S-VHS video recorder with multi-standard sound recording.

Description

Video recorder with improved sound recording

The invention is based on a video recorder according to the preamble of claim 1. Such a video recorder is known as a so-called VHS video recorder or S-VHS video recorder with HiFi sound recording by means of frequency-modulated sound carriers.

In Nordic countries such as Sweden, Finland, Norway it is known, in addition to the usual picture signals and sound signals, a digital sound signal for two languages or for stereo in the form of a so-called NICAM carrier with DOPSK (differentially encoded guadrature phase shift) modulation keying method). This sound carrier has a frequency of 5.85 MHz.

Conventional VHS video recorders are not intended and also not suitable for recording such an additional sound carrier. For the recording of the sound information of such a NICAM signal, it is therefore necessary to decode the NICAM signal and the NF sound signals obtained thereby on a longitudinal track running parallel to the band edge as NF signals or in the form of frequency-modulated sound carriers along the Record helical traces. Then, however, the recording of the actual sound signal on the longitudinal track or the helical track would no longer be possible. It would also go through the decoding and re-encoding reduces the quality. The quality features of NICAM would thus be partially lost in the recording, as would the consignment identification signals contained in the NICAM signal.

The invention is based on the object of designing a video recorder in such a way that the NICAM signal can also be recorded with full quality, being compatible with the previous sound recording, and the quality features of NICAM are retained in full.

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

The invention is based on the following consideration. In addition to two recorded FM sound carriers, there is sufficient frequency bandwidth available in the lower magnetic layer in which a frequency-reduced NICAM sound carrier can be recorded. The possibility of recording an additional signal in a lower magnetic layer independently of the signal in the upper magnetic layer is therefore advantageously used for recording an additional sound signal.

By recording the NICAM sound carrier in the lower magnetic layer there are several advantages. The previous customary recording of LF sound signals on the longitudinal track of the magnetic tape and with frequency-modulated sound carriers along the oblique tracks in the deeper layer can be completely preserved. The result is a Tσn multinorm recorder which can record the LF signals, the sound carriers frequency-modulated with the sound signals and the NICAM sound carriers independently of one another. The special quality features of the NICAM signal are completely preserved, _ _. _

because decoding and re-encoding of the NICAM signal is not necessary. By mixing the NICAM sound carrier with a mixing carrier that is coupled to the line frequency, time errors in the sound carrier are automatically compensated for during playback. Crosstalk between neighboring. th tracks in the lower layer is largely ausge¬ on, because a space between these tracks, a - so-called turf is provided ^'. In addition, high crosstalk attenuation is achieved between the frequency-reduced NICAM sound carrier in the lower magnetic layer and the image signals in the upper magnetic layer, because these signals are recorded in two different magnetic layers. This separate recording acts like a recording on separate tracks or separate recording media. The invention is particularly advantageously applicable to an S-VHS video recorder. The circuitry is low because the heads and associated circuits for recording in the deeper magnetic layer are already present in a video recorder with hi-fi sound. Preferably, a frequency-selective circuit is provided during recording and / or during playback, which detects the presence of the NICAM-type sound carrier. When this sound carrier is recognized, this circuit generates a switching voltage which automatically switches the recording circuit or the playback circuit of the recorder to operation with the sound carrier of the NICAM type. The invention is not limited to a NICAM sound carrier, but can be used in general for sound carriers which are modulated with digital sound signals in the NICAM manner.

The invention is in the following with reference to the drawing on a

Exemplary embodiment explained. Show in it

Fig. 1 shows the frequency spectrum of the signals in the upper

Magnetic layer, Fig. 2 shows the frequency spectrum of the signals in the __ __

deeper magnetic layer and the mixing carrier, Fig. 3 is a block diagram for recording and Fig. 4 is a block diagram for playback.

In the following description, the symbols used have the following meaning and values:

kHz, line requency MHz, frequency of F MHz, frequency of Fm MHz, frequency of N MHz, frequency of Nm

MHz, frequency of Ml 6 = 560xfH = 8.75 MHz, frequency of M2

F = modulated PAL color support

Fm = color carrier with reduced frequency (color under)

Ml = mixed carrier for converting F into Fm

M2 = mixed carrier for converting N to Nm

N = NICAM sound carriers

Nm = frequency-reduced NICAM sound carriers

Tl = frequency-modulated sound carrier with 1.4 MHz ± 0.2 MHz T2 = frequency-modulated sound carrier with 1.8 MHz ± 0.2 MHz

the following applies:

f5 - fl = f2 f6 - f3 = f4

According to FIG. 1, the image carrier B frequency-modulated with the luminance signal Y is recorded with magnetic heads K 1 with a gap width of 0.2 μm in the upper layer S1 of the magnetic tape T in the frequency range of approximately 1.2-10 MHz. The hatched static frequency range extends from 5.4 - 7.0 MHz. In the frequency range below B, the frequency carrier Fm, also called "color under", is recorded.

According to FIG. 2, two frequency-modulated sound carriers T1, T2 are first recorded in the lower layer S2 of the magnetic tape T with the magnetic heads K2 having a larger gap width of approximately 0.4 ^'to 0.45 μm. The received NICAM sound carrier N is converted with the mixed carrier M into the sound carrier Nm with a reduced frequency at a frequency of 2.9 MHz and recorded in this frequency position. Tl, T2, Nm are thus recorded, while N and M 'are not recorded. When recording, first the recording according to FIG. 2 and then the recording according to FIG. 1 takes place. The recording according to FIG. 2 in the upper layer S1 is deleted again.

In Fig. 3, the CVBS-PAL signal at the terminal 1 in the isolating stage 2 is split into the luminance signal Y and the modulated color carrier F. Y passes through the sub-pre-amplification stage 3, the main pre-emphasis stage 4, and the amplitude limiter 5 to the FM modulator 6, which supplies the image carrier B to the adder stage 8 via the amplifier 7. The ink carrier F is fed to the converter 10 via the bandpass 9 with a pass range of 4.43 + 0.6-0.8 MHz. The line synchronizing pulses are separated from Y in the separating stage 11 and converted in the converter 12 to the frequency f5 of the mixed carrier M1. The mixed carrier M1 passes through the high pass 13 to the other input of the converter 10. In the converter 10, the color carrier F is converted to the color carrier Fm with the frequency f2, which passes through the low pass 14 to the other input of the adder 8. The adder 8 supplies the signal according to FIG. 1, which is recorded on the magnetic tape T with the heads K 1. With the antenna 15, a transmitter signal is received with a NICAM sound carrier and processed in the tuner 16. In the isolating stage 17, the NICAM sound carrier N is separated and fed to the converter 19 via the bandpass filter 18 with a pass band of 5.85 ± 0.4 MHz. The converter 19 supplies the frequency-reduced NICAM sound carrier Nm with the frequency f4, which reaches the adder 21 via the bandpass filter 20 with the pass band of 2.9 ± 0.4 MHz. The sound carriers T1, T2 are also fed to the adding stage 21. 2 reaches the heads K2 via the amplifier 22 and is recorded there on the magnetic tape T.

FIG. 4 shows the playback circuit for the recording circuit according to FIG. 3. From the output of the switch 23, which switches between the heads K1, the modulated image carrier B passes through the delay stage 24 and the amplitude limiter 25 to the FM demodulator 26, which supplies the luminance signal Y. This passes through the low-pass filter 27 with a cut-off frequency of approximately 5 MHz and the deemphasis stage 28 to the terminal 29. The color carrier Fm reaches the converter 31 via the low-pass filter 30 with a cut-off frequency of 0.7 MHz to the isolating stage 32, which delivers line-frequency pulses with the frequency fH to the converter 33. The converter 33 supplies the mixing carrier M1 with the frequency f5, which passes through the low-pass filter 34 to the other input of the converter 31. The converter 31 supplies the color carrier F with the frequency fl, which reaches the terminal 37 via the bandpass 35 and the delay stage 36 with a delay time of two lines. In the adder 38, the CVBS signal is formed from Y and F, which is available at terminal 39 for image reproduction.

The signal according to FIG. 2 is sampled with the heads K2. From the exit of the track switch between heads K2 the switch 40, the two sound carriers Tl, 2 are evaluated with the bandpass filter 41 and fed to the FM demodulator 42. The LF audio signals NF1, NF2 obtained in this way reach inputs of the antenna modulator 43, to which the CVBS signal is also fed via the line 44. With the pass band 45 with a pass band of 2.9 ± 0.4 MHz, the sound carrier Nm is evaluated and fed to the converter 46. The line-frequency voltage with the frequency fH is converted in the converter 47 to the mixed carrier M2 with the frequency f6 and fed to the other input of the converter 46 via the bandpass 50. The converter 46 again supplies the original NICAM sound carrier N with the frequency f3, which reaches the antenna modulator 43 via the bandpass 48. The antenna ^■ modulator 43 generates an RF carrier at terminal 49, the ^'ignalen with the composite video signal, the two sound NF1, NF2 and the NICAM Tonträ¬ N eng is modulated.

Terminal 49 is preferably connected to the antenna input of a television receiver which also contains a NICAM decoder. With a frequency-selective circuit, the presence of the NICAM sound carrier N with the typical frequency of 5.85 MHz can be recognized and a switching voltage can be generated which, when the NICAM sound carrier N is present, automatically switches over to the output of a NICAM decoder causes. Such a detection and switching device can also be contained in the recorder itself, e.g. the circuit for processing. to switch on the NICAM sound carrier only in the presence of a recorded NICAM sound carrier.

The magnetic heads Kl have an azimuth angle of ± 6 °, while the magnetic heads K2 have an azimuth angle of ± 30 °. The recording in the upper layer S1 according to FIG. 1 is preferably carried out without a space, so-called turf. The recording with K2 in the deeper layer S2 takes place with a O 1/17628 _ ₈ . __ _

ne so-called lawn. This lawn is advantageous because, due to the lower frequencies, crosstalk attenuation by the azimuth angles is no longer sufficiently effective. The crosstalk between adjacent tracks is thus largely avoided by the azimuth angle at Kl and by the lawn between the tracks at K2.

Claims

_ Q _Patent claims

1. Video recorder with improved sound recording, in the case of the first magnetic heads (Kl) having a small gap width in an upper magnetic layer (Sl) of the tape (T), an image carrier (B) modulated with the luminance signal (Y) and having second magnetic heads (K2) having a larger gap width frequency-modulated sound carriers (T1, T2) are recorded in a lower lying magnetic layer (S2) with sounds, characterized in that in the lower layer (S2) with. the magnetic heads (K2) in frequency multiplex with the sound carriers (T1, T2) additionally a modulated with digital sound signals, in which. Frequency reduced sound carrier (Nm) of the NICAM type is recorded.

2. Recorder according to claim 1, characterized in that a frequency-selective circuit is provided during recording and / or during playback, which recognizes the Tonträ¬ ger (N, Nm) of the NICAM type and automatically the sound channel on the recording or playback of this sound carrier.

3. Recorder according to claim 1, characterized in that during the playback of the tape (T) scanned Tonträ¬ ger (Nm) with a mixing carrier (M2) is converted back to its original frequency (f3).

4. Recorder according to claim 1, characterized in that the frequency of the mixed carrier used for the frequency conversion is coupled to the line frequency (fH).

5. Recorder according to Claim 3, characterized in that the carrier (N) converted to the original frequency (f3) is applied to the input of an antenna modulator (43) is, which delivers a HF carrier modulated with the image and sound signals.

Recorder according to claim 1, characterized in that the second magnetic heads (K2) have an azimuth angle of ± 30 °.