DE4317128A1 - Video recorder - Google Patents

Abstract

In the case of a VHS video recorder, a picture (image) carrier which is frequency modulated by means of the luminous density (luminance) signal, and a so-called colour under-colour carrier of reduced frequency are respectively recorded in a helical scan. In this type of recording, during replay the colour signals have only a limited bandwidth of approximately 600 kHz, and so the image sharpness is impaired. The object is to improve the colour recording without additional circuitry outlay and without increasing the range of frequencies used. Along a helical scan (S), the first step is to record the image carrier (BT) by means of a first head (K1) over the entire depth of the magnetic coating (M), after which the PAL colour carrier (F), whose frequency position is unaltered, is recorded by means of a second head (K2) in a second track (S2) which is situated inside the first track (S1) and extends only over a part of its width and likewise over the entire depth of the magnetic coating (M). This type of recording is also designated as track trenching. Particularly for a VHS or S-VHS video recorder. <IMAGE>

Description

The invention relates to a video recorder according to the Preamble of claim 1. Such a video recorder is known as a VHS or S-VHS video recorder. The Frequency of the color carrier from 4.43 MHz to about 600 kHz reduced and the so-called color under Color carrier below the frequency spectrum of the image carrier recorded. Through this type of recording, Color signals when playing back only a bandwidth of about 600 kHz. This means reduced playback Sharpness for the color.

The invention has for its object a video recorder train that without additional circuitry and without Increase the band consumption the color signals with full band wide can be recorded and thus during playback the sharpness of the image is increased in terms of color.

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

In the invention, the image carrier with a first head in a first track essentially all over Depth of the magnetic layer and then the frequency and its range of PAL color carriers unchanged with one second head recorded in a second track within the first track lies only over part of its width and also extends over the entire depth of the magnetic layer. This way of recording an additional track within A track is generally also referred to as "track trenching". The second track is preferably in the middle of the first Track and has a width of 16-20 µm, while the first track has a width of 49 µm. So the second track is sort of punched into the first track.  

In a preferred embodiment of the invention is in the second lane an unmodulated pilot carrier below of the frequency spectrum of the color carrier recorded. This pi solder carrier is used for reproduction by mixing with that of Ribbon scanned ink carrier for time error compensation of the Color carrier.

The previously used color under carrier in the first track can omitted. Then the frequency spectrum of the with the light density signal frequency-modulated image carrier further to deep Frequencies extended and thereby sharpness and interference stand to be increased. It is also possible to change the color under Trä in the first track in addition to one To ensure compatibility with previous recorders. Then it is possible to choose the color signals from the narrow-band color under carrier or the invention to win recorded color carriers with full bandwidth. In the second track can also be frequency-modulated Recordings can be recorded.

According to a further development of the invention, an additional PCM audio signal recorded. For the record there is various possibilities. The PCM tone signal can at each The beginning and / or end of a helical track are recorded, in an area that is not from the recorded video signal is exploited. This free area can e.g. B. 10-20 ° of Head drum rotation. Since the recording of the PCM Sound signal only during part of the time of a picture is possible, the PCM sound signal when recording accordingly time-compressed and again during playback time expanded. This will change the bandwidth of the PCM audio signal although increased. The recording is also increased Bandwidth possible because then the high available Recording bandwidth within the helical tracks up to 7 MHz is available.

According to another variant, a PCM audio signal is passed along a longitudinal track running parallel to the belt edge  recorded. This longitudinal track can, for. B. between the Control lane and the area described by the video signal lie or the signal of the control lane or LF sound signal can be superimposed. The range of such Longitudinal track is in itself not sufficient for a PCM audio signal. Therefore, the PCM audio signal is preferred for recording subjected to data compression in a longitudinal track. Here z. B. signal components according to one of the known methods suppressed from a psychoacoustic point of view. By a Such data reduction in the PCM audio signal can reduce the bandwidth of the sound signal can be considerably reduced. A Time compression is not necessary because the longitudinal track is without Interruption can be described with the PCM audio signal.

The invention has several advantages. As a result of that the PAL color carrier unchanged, i.e. without changing its Frequency and bandwidth is recorded for the Color rendering the full transmitter quality regarding sharpness and signal to noise ratio reached. By recording after the track trenching principle, the tape consumption is not increased because still all the necessary signals the same track width take like a normal VHS recorder. The circuit of the Recorders, however, is significantly simplified because both the recording as well as during playback the previously required Components for reducing and increasing the frequency of the color carrier are eliminated. By recording the Pilot carrier in the second lane is also at Playback with little circuitry a time error enables the same color carrier. The invention is both at VHS as well as S-VHS recorders applicable.

The invention is explained below with reference to the drawing. Show in it

Fig. 1, 2, frequency spectra of the recorded signals,

Fig. 3 is a track picture and

Fig. 4 is a block diagram of the recorder for recording and playback.

The designations used in the figures for the individual signals have the following meaning.
BT with the luminance signal Y frequency-modulated image carrier
F with two color signals quadrature modulated PAL color carrier with 4.43 MHz
Fz ink carrier scanned from the tape with time errors
Fd 8.86 MHz color carrier doubled in frequency with time errors
P1 unmodulated pilot carrier with 4.43 MHz
P2 pilot carrier with halved frequency of 2.2 MHz
T1 modulated sound carrier for sound signal L with 1.4 MHz
T2 modulated sound carrier for sound signal R with 1.8 MHz
Y luminance signal.

Referring to FIG. 1, the frequency-modulated with the luminance signal Y image carrier BT, which occupies a frequency range of about 1.2 to 7.3 MHz, is recorded in the first track of the magnetic tape T S1. The width of track S1 corresponds to the usual track width of a VHS recorder of approximately 49 µm. The recording extends over the entire depth of the magnetic layer M, which is arranged on the carrier material B.

Referring to FIG. 2, the two frequency modulated sound carriers are T1 and T2, the pilot carrier and P2 of the original PAL color carrier F having a frequency range of about 3.2 to 5.7 MHz additive recorded in the second track S2. The track S2 lies in the middle of the track S1 and has a width of approximately 20 µm. Track S2 is thus punched in the middle of the first track S1 according to the so-called track trenching principle. When recording track S2, which is done with a separate head after recording track S1, the corresponding part of track S1 is thus deleted again. Decoupling of the two tracks S1 and S2 during playback can be achieved by different azimuth angles for the signals of the two tracks, e.g. B. ± 6 ° for track S1 and ± 30 ° for track S2.

Fig. 3 shows the position of the two tracks S1 and S2 in the form of oblique tracks on the magnetic tape T. Parallel to the tape edge are the track S3 for an LF sound signal, the track S4 for the control signal and possibly another track S5 for a PCM Sound signal.

Fig. 4 shows the recording circuit REC in the upper part. The luminance signal Y is modulated in the FM modulator 1 onto the image carrier BT in frequency modulation, which is fed to the head K1 via the amplifier 2 and recorded on the magnetic tape T in the track S1. The frequency-modulated sound carriers T1, T2 of the original PAL color carrier F and the pilot carrier P2 are added linearly in the adding stage 3 . The resulting signal T1 + T2 + F + P2 according to FIG. 2 is fed to the head K2 via the amplifier 4 and likewise recorded on the magnetic tape T in track S2. The gap length of the head K2 is approximately 20 µm. The pilot carrier P2 is obtained with the frequency divider 10 with the divider factor 2 from the pilot carrier P1, which is generated in the quartz oscillator 11 .

Fig. 4 shows the playback circuit PB in the lower part. The image carrier BT scanned with the head K1 from the tape T passes via the amplifier 2 to the FM demodulator 5 , which again supplies the luminance signal Y. The sum signal T1 + T2 + P2 + F sampled with the head K2 passes via the amplifier 4 equally to the high-pass filter 5 with a cut-off frequency of 3 MHz, the band-pass filter 6 with a pass-through point at 2.2 MHz and the low-pass filter 7 with a cut-off frequency of 2 MHz. The high-pass filter 5 supplies only the color carrier Fz, which is subject to time errors, to the mixing stage 8 , to which the pilot carrier P1 is also fed by the oscillator 11 . At the output of the mixer stage 8 there is the color carrier Fd, doubled in frequency, at 8.86 MHz, which is fed to the mixer stage 9 . The bandpass filter 6 supplies only the pilot carrier P2, which is converted into the pilot carrier P1 in the frequency doubler 12 . In the mixing stage 9 , Fd and P1 are mixed, as a result of which the original PAL color carrier F with the original frequency 4.43 MHz and without timing errors is produced at the output of the mixing stage 9 . The low pass 7 provides the two sound carriers T1, T2. With the head K1, a so-called color under color carrier with a frequency of approximately 630 kHz can additionally be recorded in the usual way below the frequency spectrum of the image carrier BT. Then the color carrier F would be linearly added to the image carrier BT at the output of the modulator 1 by mixing the frequency.

The manner in which the time error compensation is carried out in the playback circuit according to FIG. 4 is explained in more detail below. A time error, also called jitter, of ± 1% is assumed. The recorded pilot carrier P2 has a frequency of 2.2 MHz ± 1%, corresponding to a time error of ± 22 kHz.

During playback, the pilot carrier P1 of 4.4 MHz ± 44 kHz is obtained by frequency doubling in the frequency doubler 12 .

The color carrier Fz scanned from the tape has the PAL original fre quenz von 4.43 MHz ± 1%, corresponding to a time error of ± 44 kHz.

This color carrier is mixed in mixing stage 8 with the unmodulated pilot carrier of 4.4 MHz ± 0%, that is, without a time error.

This mixture results in the ink carrier Fd at 8.86 MHz ± 1%, corresponding to a time error of ± 44 kHz.

This color carrier is mixed with the pilot carrier P1 mentioned from 4.4 MHz ± 1% corresponding to a time error of 44 kHz.

Mixing Fd and P1 in mixing stage 9 thus results in the original PAL color carrier F with a frequency of 4.4 MHz ± 0 kHz, that is to say a color carrier which is freed of time errors with the aid of the pilot carrier.

Claims (9)

1. Video recorder, in which each along a helical track (S) of the magnetic tape (T) with the luminance signal (Y) modulated image carrier (BT) and a quadrature-modulated color carrier (F) are recorded, characterized in that the next the image carrier (BT) with a first head (K1) in a first track (S1) essentially over the entire depth of the magnetic layer (M) and then the PAL color carrier (F), which has not changed in frequency, with a second head (K2) in one second track (S2) is recorded, which lies within the first track (S1), extends only over part of its width and also over the entire depth of the magnetic layer (M). 2. Recorder according to claim 1, characterized in that the second track (S2) lies in the middle of the first track (S1). 3. Recorder according to claim 1, characterized in that in the second track (S2) additionally an unmodulated pilot carrier (P2) below the frequency spectrum of the color carrier (F) is recorded. 4. Recorder according to claim 1, characterized in that in the first track (S1) below the frequency spectrum of the image gers (BT) additionally a quadrature modulated color under Ink carrier is recorded. 5. Recorder according to claim 1, characterized in that in the first track (S1) without a color support Frequency range of the image carrier (BT) in the lower frequency area that is encased in itself by a color under color support is taken, is extended. 6. Recorder according to claim 1, characterized in that the Playback (PB) of the scanned ink carrier (Fz) with the local Lich generated pilot carrier (P1) on a color carrier (Fd) with increased frequency implemented and this with the abge from the band  felt pilot carrier (P1) on one freed from time errors Color carrier (F) is implemented with the standardized frequency. 7. Recorder according to claim 1, characterized in that the Record the signals in the two tracks with under different azimuth angles. 8. Recorder according to claim 1, characterized in that in each case at the beginning and / or at the end of a helical track (S1, S2) outside the range described with the video signal time-compressed PCM audio signal is recorded. 9. Recorder according to claim 1, characterized in that in a longitudinal track running parallel to the belt edge a one PCM audio signal subjected to data reduction recorded becomes.