DE4218120A1 - VHS video recorder - allows optional high quality display mode together with usual VHS mode - Google Patents

Abstract

The video recorder has a pair of heads (K1) of smaller gap width to record a picture carrier (BT) and a colour carrier (F) in an upper magnetic layer of a magnetic tape (T). A second pair of heads (K2) of larger gap width records sound carriers in a lower magnetic layer. The tape (T) is fed over a drum (21) at a nominal speed (Vo). The recorder has switches (Sa-Si) to switch over to a second operation mode. In this mode, the recording and playback speed (V2) is switched to double the nominal value (2Vo). A line sequential colour carrier (Fs) frequency modulated with the colour difference signals (R-Y,B-Y) is recorded in the space between the picture-colour carrier and sound carrier tracks by a third pair of heads (K3) on the drum. ADVANTAGE - Provides very high quality playback esp. for colour signals.

Description

The invention relates to a video recorder according to the Preamble of claim 1. Such a video recorder is a so-called VHS video recorder with HiFi sound recording known. With such a recorder, the color difference signals with a reduced in frequency Color carrier, a so-called color-under carrier, below the frequency spectrum of the fre with the luminance signal record-modulated image carrier recorded. By Art the recording results in particular with regard to the Color a limited playback quality. By the nature of the Color recording have the color difference signals at the how only a bandwidth of 0.5 MHz, so that the Color rendering is not a sufficient interference in many cases distance and bandwidth result.

Professional video recorders are known, for which the luminance signal and the color difference signals with vol bandwidth and during playback practically transmitter quality is achieved. Darbled recorders are however very expensive and not for the normal consumer available.

The invention has for its object to a recorder create, in addition to the usual VHS operation either Recording company with significantly higher quality, esp special in terms of color recording, enables. These Object is achieved by the invention specified in claim 1 solved. Advantageous developments of the invention are in specified in the subclaims.

The recorder according to the invention thus enables compatible the unchanged VHS operation either simply by Um switch a second operating mode with a significantly higher qua lity with the quality of professional video recorders is comparable. The additional circuitry ge  ring, because practically all components also work be exploited with high quality and essentially only some switches and simple additional stages required are. The effort to switch to double Longitudinal speed is low because the measures for this are in a normal recorder for double tape search speed already exist. The quality association is used both for the luminance signal and for the color signals achieved. Bandwidth and signal to noise ratio of Luminance signals are improved in that the previous so-called color-under carrier is omitted and therefore the with the luminance signal frequency-modulated image carrier total available recording bandwidth of the first head couple can take. The quality of the color signals is in its improved in that the color difference signals by frequency modulation of a color carrier between the Spu with the luminance signal in separate tracks be drawn. Then also stands for the color difference sign le the full recording bandwidth available so that these signals with their full transmitter bandwidth of 1-1.5 MHz can be recorded. By frequency modulation are also stripped amplitude fluctuations tet.

Crosstalk between the luminance signal and the Color signals are recorded by the spatially separate also excluded. Also for those in the longitudinal track LF audio signals recorded an improvement because the tape at twice the speed of 47.5 mm in the second moves and thereby the full sound quality of HiFi audio cassettes is achieved. Also for the second loading mode of operation with twice the longitudinal speed of the magnetic tape this is always the case with video cassettes with a playing time of 300 minutes towards 2.5 hours of high quality recording possible.  

In a development of the invention, those with Tonsi gnalen frequency-modulated sound carrier also with the third ten head pair in frequency division multiplex with the color carrier draws. The third pair of heads then reads during playback the recorded ink and the recorded sound carrier. There is an additional one on the third pair of heads Sound channel connected for processing the sound carrier. According to a development of the invention, the second head couple who writes the recordings on recording, like this offset from the first pair of heads on the head drum arranged that when playing the second pair of heads can read traces written by the third pair of heads. The one with the third pair of heads between the tracks of the first Head pair of written recordings can then in the How read with the second pair of heads, although the ses head pair for writing these tracks is provided. This has the advantage that for third pair of heads no circuit for processing and demodu lation of the sound carrier must be provided and the need anyway agile sound channel for those recorded with the second pair of heads Neten sound carrier can be used.

The third pair of heads preferably has an azimuth angle of ± 30 ° to avoid crosstalk between neighboring Spu guarantee. Then the traces of the third Head pair without space, i.e. without lawn, in the Zwis shouted between the traces of the first pair of heads be. According to a development of the invention third pair of heads an azimuth angle of 0 °. Has this solution following advantage. The time error one scanned from the tape th signal, which is specifically created by "dancing" the video head the trace created during the reading process is from the respective Azi Mutual angle dependent and very small at an azimuth angle of 0 ° or null. If now the azimuth angle of the third head pair res is zero, kick in that sampled by the third pair of heads practically no time errors occurred. So far the circuits for time error compensation, so-called TBC  (time base correction) circuits used to do this through the heads with an azimuth angle of ± 30 ° im Color and sound channel to reduce timing errors and on the small timing errors of the signal from the video heads with an azimuth angle of ± 6 °. This correction scarf Then the scarf is no longer required effort is simplified. Due to the azimuth angle of 0 ° However, the desired crosstalk attenuation is also eliminated between neighboring tracks. According to a training of Invention, therefore, the third pair of heads has a smaller gap longer than the space between the traces of the first Head pair, creating between the tracks of the first head pair gaps and traces of the second pair of heads, a so-called lawn occurs. The traces of the third head couple then do not have the width of 49 µm of the first head pair, but a smaller width of preferably 40 µm, so that the lawn is 4.5 µm. By such Lawn can be added to the elimination of time error correction circuits also crosstalk sufficient to be of great value.

The invention is based on the drawing to egg NEM embodiment explained. Show in it

Fig. 1 is a block diagram of a recorder for recording according to the invention,

Fig. 2 shows a head drum with mounted thereon three pairs of heads,

Fig. 3 shows the track pattern for the standard VHS operation,

Fig. 4 shows the track image for the second mode of operation with increased quality and

Fig. 5 is a block diagram for playback.

Fig. 1 shows the block diagram of a VHS or S-VHS video recorder, which can work either in normal VHS mode or in a second operating mode with increased quality. The two operating modes are described in sequence below.

1. Operating mode with VHS operation

In this operating mode, the switches Sa-Sd have the position shown. The recorder then works in normal VHS mode. Shown are the antenna 1 , the tuner 2 , the demodulator 3 supplying the composite signal, the comb filter 4 for separating the composite signal into the modulated color carrier F and the luminance signal Y, the bandpass filter 5 with a pass band at 4.43 MHz , the AGC stage 6 , the frequency converter 7 for converting the color carrier frequency f1 to the color-under frequency fm of 627 kHz, the low-pass filter 8 with a cut-off frequency of 1 MHz, the adder 9 , the speech amplifier 10 and the head pair K1 for the magnetic tape T. Y passes through the low pass 11 with a cutoff frequency of 5 MHz to the FM modulator 12 , which delivers the Y frequency modulated image carrier BT to the adder 9 via the high pass 13 with a cutoff frequency of 1 MHz. With the head pair K1 with an azimuth angle of ± 6 ° and a gap width of 0.35 µm, the image carrier BT frequency-modulated with the luminance signal Y is recorded on the magnetic tape T and below the frequency spectrum the frequency carrier Fm reduced in frequency is recorded.

The sound signals L, R are modulated in the FM modulator 14 two sound carriers T1, T2 in frequency modulation, the head pair K2 with an azimuth angle of ± 30 ° and a gap width of 0.4 microns in a lower magnetic layer of the magnetic tape T be recorded. The third pair of heads K3 is not in operation in this mode and is switched off by the switch Se.

2. Operating mode with increased quality

In this operating mode, the switches Sa-Sd have been switched to the position not shown and are now causing the following changes. Via the closed switch Sb, the color carrier F reaches the demodulator 15 , which supplies the two color difference signals RY and BY. The color difference signals are converted into line-sequential color difference signals in the simultaneous / serial converter 16 , which in the simplest case consists of a line-frequency operated switch, which are converted into a color carrier Fs in FM with a frequency of 4.3 in the FM modulator 17 MHz and a frequency shift of 3.8 MHz-4.8 MHz can be modulated. The line sequential with the color difference signals RY and BY modulated Farbträ ger Fs passes over the bandpass filter 18 with a pass band of 2.2 MHz to 6.4 MHz via the adder 19 , the speech amplifier 20 and the closed switch Se on the third pair of heads K3 . The head pair K3 has an azimuth angle of ± 30 ° and a gap width of 0.4 µm. With the pair of heads K3, the color carrier Fs frequency-modulated with the broadband color difference signals RY and BY is thus recorded.

The capstan drive 21 is switched so that in this operating mode the magnetic tape T is transported with the double VHS speed 2 Vo. Due to this double longitudinal speed, there is inevitably a space of 49 µm between the written oblique tracks with a width of 49 µm.

The ink carrier Fs is recorded in the space between the tracks written by the head pair K1. The switch Sc short-circuits the high-pass filter 13 so that the lower frequency range of 0-1.2 MHz is no longer suppressed. The image carrier BT generated in the FM modulator 12 then takes up the full available recording bandwidth of the head pair K1. The closed switch Sa suppresses the modified color carrier Fm, so that it no longer reaches the head pair K1. The flipped switch Sd also feeds the modulated sound carriers T1, T2 to the pair of heads K3. The sound carriers T1, T2 are recorded in frequency division multiplexing with the color carrier Fs with the head pair K3.

Fig. 2 shows the arrangement of the pairs of heads K1, K2, K3 on the head drum D. When the angular position of the head pair K1 to 0 is assumed °, is the pair of heads K2 at an angle of 420 and the pair of heads K3 at an angle of 4.583 °, which corresponds to a spacing of 8 lines (8 H).

Fig. 3 shows the track image for the first operating mode for VHS operation. The tracks S1 of the pair of heads K1 with a width of 49 microns are written together without a lawn ben. The tracks S2 of the pair of heads K2, which contain the modulated sound carriers T1, T2, lie centrally over the tracks S1 and are recorded in a lower magnetic layer below S1. This track picture corresponds to the standard track picture usual at VH.

Fig. 4 shows the track image for the second mode with he increased quality. Due to the doubled longitudinal speed 2Vo, the tracks S1 described with K1 now have a spatial distance with the width of these tracks, that is, 49 bin. At this distance, the tracks S3 of the head pair K3 are written without a space. The exact location is achieved by a special angular position of the head pair K3 on the Kopftrom mel D according to FIG. 2. The tracks 52 of the head pair K2 have such a position that they are half over tracks S1 and the other half over tracks S3. This is also achieved by a special angular position of the head pair K2 on the head drum D according to FIG. 2.

Fig. 5 shows the block diagram for the playback, which is also explained below for the two different operating modes.

First operating mode with VHS operation

In this operating mode, the switches Sf-Si are like the one in the position shown. The recorded color carrier Fm passes from the head switch 22 via the low pass 23 with a cutoff frequency of 1.2 MHz to the converter 24 , which converts the reduced frequency fm back to the original value f1 of 4.43 MHz. The color carrier F reaches the adder 26 via the bandpass 25 with a pass band at 4.43 MHz and the switch Sf. The image carrier BT reaches ge via the high-pass filter 27 with a cutoff frequency of 1.2 MHz to the FM demodulator 28 , which produces the luminance signal Y lie via the low-pass filter 29 with a cutoff frequency of 3 MHz. As a result, the CVBS signal is again available at the output terminal 30 . The sound carriers T1, T2 pass via the head switch 31 and the switch Si to the FM demodulator 32 , which again supplies the two sound signals L and R. The head pair K3 does not deliver a signal because no signal has been recorded with K3 in this operating mode. The drive 21 is controlled so that the magnetic tape T is driven at the rated speed Vo according to the VHS standard of 23.39 mm / s.

Second mode of operation with increased quality

The switches Sf-Si are now switched to the position not shown. S6 causes the addition stage 26 to no longer receive a color carrier because no color carrier has also been drawn on with K1. The closed switch Sg has the effect that the lower frequency range of 0-1.2 MHz is no longer suppressed in the modulated image carrier BT. This is necessary because this frequency range was not suppressed when recording in this mode and the image carrier BT takes up the full recording bandwidth of the head pair K1. The closed switch Sh has the effect that the luminance signal Y is no longer limited in bandwidth and is therefore available with a full bandwidth of 5 MHz. The head pair K3 now delivers the frequency modulated color carrier Fs with the color difference signals, which reaches the FM demodulator 34 via the bandpass 33 with a pass band of 2.2 MHz to 6.4 MHz. This supplies the color difference signals RY, BY sequentially. These signals reach the serial / parallel converter 36 via the TBC (time base correction) circuit 35 used for time error compensation. The converter 36 includes a line delay line and a line-frequency operated switch and delivers at its output the simultaneous color difference signals RY and BY with full bandwidth of about 1-1.5 MHz to the matrix 37 , which also has the broadband luminance signal via line 38 Y is supplied. The matrix 37 supplies at its outputs the broadband color signals RGB and the synchronizing signal S, which are available at a SCART socket for high-quality color reproduction.

With the bandpass 38 , an additionally recorded pilot carrier P of 0.125 MHz = (8 _* fH) is evaluated and supplied to level 35 for time error compensation. The pilot carrier P ge also reaches the servo circuit 40 , which is additionally supplied with the synchronizing signal S from the demodulator 28 via the synchronizing signal separating stage 41 . The servo circuit 40 be an automatic switchover of the drive 21 from the speed Vo to 2Vo. The switchover to 2Vo takes place when the pilot carrier P is recognized as a criterion for the second operating mode. The circuit 42 also generates a switching voltage on the pin 16 of a scart socket, which automatically causes a switchover to the described two operating mode with increased quality when it is played again.

In the following two special features are described, which can also be used in FIGS. 1 and 5.

When recording in the second mode of operation, the sound carriers T1, T2 are fed to the head pair K3 via the switched switch Sd and recorded in the manner described in frequency division multiplexing with the color carrier Fs. The head pair K2, however, has such a spatial angular position on the head drum D that K2 reads the tracks written with K3 during playback. This solution is based on the knowledge that by ei ne special angular position of K2 on the head drum D, in particular at an angle of 420 to K1, can be achieved that K2 in the first mode of operation, ie with VHS-Be operated, the center reads tracks S2 written via S1, but reads tracks S3 according to FIG. 4 between tracks S1 in the second operating mode. When playing in the two-th mode of operation, the sound carriers T1, T2 can then be read with the head pair K2 despite their position on the tracks S3. This has the advantage that the sound channel for head pair K2, which does not exist in the first mode of operation, can be used to evaluate the sound carriers T1, T2 read from tracks S3. A separate sound channel with the corresponding components such as equalizer and amplifier for the head pair K3 is then no longer necessary. The head pair K2 is thus used to read different tracks in the two operating modes.

A second variant consists of the following:

The azimuth angle A of the pair of heads K3 is equal to 0 °. The time errors in the sampled signal depend on the azimuth angle and are more small at an azimuth angle of 0 °. The azimuth angle of 0 ° for K3 means that a time error correction for the color carrier Fs from the head pair K3 is no longer required. The scarf device 35 in Fig. 5 can then be omitted, whereby the scarf processing effort for the recorder is reduced. The azimuth angle of 0 ° also eliminates crosstalk attenuation between adjacent tracks. In order to ensure sufficient crosstalk attenuation, the width of the tracks S3 is additionally chosen to be smaller than the gap between the tracks S1 in FIG. 4, e.g. B. not 49 microns, but 40 microns. Then there is an intermediate space or a so-called lawn of 4.5 µm between the tracks S1 and S3, which is sufficient for a sufficient attenuation.

The third pair of heads K3 is preferably one of the pair of heads ren K1, K2 separate rotary transducer assigned to the the top of the head drum.

Claims (10)

1. Video recorder with a first pair of heads (K1) with a small gap width for recording an image carrier (BT) and a color carrier (F) in an upper magnetic layer (S1) and with a second pair of heads (K2) with a larger gap width for recording sound carriers (T) in a lower magnetic layer (S2) with a nominal longitudinal speed (Vo) on the head drum ( 21 ) passing magnetic tape (T), characterized in that the recor has the switch (Sa-Si) for switching to a second operating mode , in which the longitudinal speed (V) during recording and playback is switched to twice the nominal value ( 2 Vo) and in the spaces between the tracks (S1) with a third pair of heads (K3) arranged on the head drum ( 21 ) a row line frequency-modulated color carrier (Fs) is recorded with the color difference signals (RY, BY). 2. Recorder according to claim 1, characterized in that in the second mode in the first pair of heads (K1) fed signal of the modulated color carrier (F) is suppressed and that with the luminance signal (Y) frequency-modulated image carrier (BT) essentially the takes up the entire available recording bandwidth. 3. Recorder according to claim 1, characterized in that the third pair of heads (K3) in such a manner with respect to the first and second pair of heads (K1) spatially offset on the head drum ( 21 ) is arranged that in the second mode of loading Be by the third pair of heads (K3) written tracks (S3) lie between the tracks (S1, S2) written by the first and second pair of heads (K1, K2). 4. Recorder according to claim 1, characterized in that in the second operating mode the one with sound signals (L, R)  frequency-modulated sound carrier (T1, T2) also with the third pair of heads (K3) in frequency division multiplex with the Color carriers (Fs) are recorded. 5. Recorder according to claim 1, characterized in that the third pair of heads (K3) one of the other pair of heads ren (K1, K2) separate rotary transformer is assigned. 6. Recorder according to claim 1, characterized in that the gap length of the third pair of heads (K3) is smaller than the width of the space between the tracks (S1) of the first pair of heads (K1) and the third pair of heads (K3) has an azimuth angle of 0 °. 7. Recorder according to claim 1, characterized in that the second pair of heads (K2) in the second operating mode Read the in the spaces with the third head couple (K3) recorded sound carriers (T1, T2) used is. 8. Recorder according to claim 8, characterized in that the second pair of heads (K2) is mounted in such an angular position on the head drum ( 21 ) that it is in the two-th mode when playing the tracks written with the third pair of heads (K3) read. 9. Recorder according to claim 9, characterized in that the angular offset between the first pair of heads (K1) and the second pair of heads (K2) on the head drum Is 42 ° -90 °. 10. Recorder according to claim 1, characterized in that the third pair of heads (K3) has an azimuth angle of approximately ± 30 ° and a gap length of 39 microns.