DE4013078A1 - VIDEO RECORDER WITH IMPROVED COLOR RECORDING - Google Patents

Abstract

In novel television transmission systems like D2-MAC, for example, the signal quality is improved with regard to bandwidth and cross-talk. Some of this signal quality is lost when such a signal is recorded on an ordinary video recorder. The purpose is to construct a video recorder in such a way that high-quality recordings of such signals can be obtained without losing the quality parameters of the signal again thereby. The colour difference signals (R-Y, B-Y) are recorded line-sequentially by the frequency modulation of a carrier (Ft) with second magnetic heads (K2) with a wider gap in a deeper-lying layer (S2) of the magnetic tape (T). Especially for an S-VHS video recorder for recording D2/MAC signals.

Description

The invention relates to a video recorder according to the Preamble of claim 1.

With the D2-MAC system, time is in each case in one line the time compressed color difference signal and that also transmit time-compressed luminance signal, the two color difference signals line up in this form are transmitted sequentially. With this solution there are lights density signal and color signal or the two color signals never sometimes available at the same time. This will cause crosstalk avoided for these signals. Because only one at a time Signal is transmitted, the full transmission bandwidth can be used for each of these signals. By a Such signal transmission is therefore low Crosstalk and a high bandwidth.

When recording such a signal with a übli Chen VHS or S-VHS video recorder must be in a D2-MAC-De coder obtained signal re-encoded in a composite signal and in be recorded in the usual way. Through this decoding and re-encoding the quality characteristics of the MAC signal in terms of crosstalk and bandwidth partly again lost.

The invention has for its object a Train VCRs so that they have a high quality drawing of a D2-MAC signal allows without the quali physical characteristics of such a signal through the recording partially lost again.

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

The invention is based on the following consideration. The record voltage in the lower layer is due to the larger Gap width of the head only with a reduced bandwidth possible. A record of the with the luminance signal modulated image carrier would not be possible in this way. However, the color signals usually have compared to that Luminance signal a smaller bandwidth. Therefore can the recording in the lower layer with reduced Bandwidth advantageous for recording the color signals be attracted. The D2-MAC color difference signals can be in the deeper layer with almost all of its range be recorded according to the standard of about 2.8 MHz. The possibility of additional recording of a signal reduced bandwidth in a lower lying magnet So layer is in the invention for a new type used purpose.

The recording according to the invention has several advantages. The color signals no longer need in the upper layer in the Frequency division multiplexed together with the luminance signal to be drawn. This makes it possible to record Increase bandwidth for the luminance signal by the frequency spectrum of the image carrier in the lower range below 1 MHz, which is otherwise occupied by the color carrier has been expanded. In this way, for  Luminance signal can reach a bandwidth of 5.6 MHz. On the other hand, the color signals can also have a high bandwidth te will be recorded. The second layer, especially for The color signals used are similar to a separate one recording medium or a separate track. Through the Recording of luminance signal and color signals in ge separated layers there is little, hardly noticeable crosstalk between these signals. The record is compatible with previous recorders, because the previous Record the color signals with a frequency reduced color carrier below the frequency spectrum of the luminance signal can remain. At the on drawing a MAC signal the quality advantages remain signal in terms of crosstalk and bandwidth receive. Sequential recording also does not work Disadvantage because the two color differences in a MAC signal signals are present line by line anyway.

The invention is based on the drawing of an embodiment example explained. Show in it

Fig. 1 frequency spectrums for a first type of recording,

Fig. 2 frequency spectra for a second type of recording,

Fig. 3 is a block diagram for the recording and

Fig. 4 is a block diagram for playback.

The symbols used in the figures have the following meanings and values:
fH = line frequency 15.625 kHz,
fl 1 = PAL color carrier frequency 4.43361875 MHz,
f 2 = 0.62695313 MHz frequency of Fm,
f 3 = f 1 +40 fH + 1/8 fH = 5.0605718 MHz mixed frequency,
f 6 = 2.203125 MHz mixed frequency for T 1 ,
f 7 = 2.40625 MHz mixed frequency for T 2 ,
T 1 = frequency-modulated sound carrier for L with 1.4 MHz ± 150 kHz
T 2 = frequency-modulated sound carrier for R with 1.8 MHz ± 150 kHz,
T 3 = recorded sound carrier for L in the 1st field at 1.00625 MHz,
T 4 = recorded sound carrier for R in the 1st field at 0.60625 MHz,
T 5 = recorded sound carrier for L in the second field at 0.803125 MHz,
T 6 = recorded sound carrier for R in the second field at 0.4203125 MHz,
Fm = below the frequency spectrum of the image carrier, the frequency carrier is reduced in color (color under),
Ft = ink carrier recorded in the lower layer, f 2 = f 3 -f 1 = 40 fH + 1/8 fH.

Fig. 1a shows the frequency spectrum of the modulated with the luminance signal Y image carrier B with a static Fre quenzhub of 5.4-7.0 MHz, which extends approximately from 1.2-10 MHz. Below this frequency spectrum is the modified, frequency-reduced ink carrier Fm. This signal mixture is recorded with magnetic heads K 1 with a narrow gap width of about 0.2 µm in the upper layer S 1 of the magnetic tape T.

FIG. 1b shows a signal with a mixture of a Farbdif conference signal modulated color carrier Ft with a frequency deviation of 3.5-4.2 MHz, the bandwidth of which extends approximately from 1.8 to 4.5 MHz. The color carrier Ft is frequency-sequenced line sequentially with the two color difference signals BY and RY. At the frequencies 1.4 MHz and 1.8 MHz, the sound carriers T 1 , T 2 are frequency-modulated with sound signals. The signal mixture according to FIG. 1b is recorded with magnetic heads K 2 of larger gap width of approximately 0.4 to 0.45 μm in the deeper layer S 2 of the magnetic tape T. In practice, the recording according to FIG. 1b takes place with the heads K 2 . Shortly thereafter, the recording according to FIG. 1a takes place with the heads K 1 , in which the recording already existing with K2 in the upper layer S 1 is deleted again. The signals according to Fig. 1a and Fig. 1b are thus spatially separated from each other with high crosstalk attenuation recorded in the two layers S 1 , S 2 . The two magnetic heads K 2 have an azimuth angle of ± 36 °.

Since the color difference signals are recorded by the color carrier Ft in layer S 2 , the color carrier Fm in layer S 1 can also be omitted. The frequency range taken up by the image carrier B can then be extended to lower frequencies up to approximately 0.1 MHz, as indicated by the dashed curve 1 . If Ft and Fm are both recorded, Fm can instead be supplied with demodulated Fm as a substitute signal to the color channel during playback in the event of a fault in Ft. With this type of recording with Ft, the recorded color difference signals have a bandwidth of approximately 2.15 MHz, which corresponds to approximately 77% of the standardized bandwidth of a D2-MAC transmitter and enables perfect color reproduction. Both Y and the color difference signals can both be recorded in the separate layers S 1 , S 2 each with their approximately full bandwidth (Y bandwidth about 89% 5.0 MHz instead of 5.6 MHz).

Fig. 2 shows another variant of the recording. The modulated image carrier B is recorded in layer S 1 as in FIG. 1a. The color carrier Fm is omitted. Instead, four sound carriers T 3 , T 4 , T 5 , T 6 are recorded, in each case the two sound carriers T 6 , T 5 during a field or a VHS inclined track and the colored carriers T 4 in the next field or the next inclined track , M 3 . The frequencies of the two sound carriers are switched from field to field or from helical track to helical track between different values. This has the following purpose. The crosstalk attenuation caused by the azi mutwinkel of the heads between adjacent tracks is only ge ring at frequencies below 1 MHz, so that an impermissible crosstalk between the sound carriers of adjacent tracks can occur. Therefore, the frequencies of the two recorded for the stereo channels R, L recorded carriers from field to field or from track to track. Such a switch is described in more detail in DE-OS 33 06 978. In the second layer S 2 , the recording of sound carriers is therefore no longer necessary. Therefore, according to FIG. 2b, the frequency range taken up by the color carrier Ft can be extended further down to about 1 MHz, with the same static modulation boost as in FIG. 1b. With this type of recording, a bandwidth for the color difference signals of approximately 2.8 MHz can be achieved.

According to a further development, the luminance signal Y is recorded in accordance with FIG. 1a or FIG. 2a without the synchronization signal. The pure BA signal can then take up the entire modulation stroke. This increases the useful stroke by around 30%, which results in a larger signal-to-noise ratio. Instead, the synchronizing signal is recorded together with the color difference signals RY, BY with the color carrier Ft. According to another further development, the color difference signals in the recording are regulated in amplitude in such a way that the full FM modulation stroke of 3.5-4.2 MHz is always used regardless of their amplitude. The amplitude of the color difference signals is usually increased and falsified. In addition, an identification signal is transmitted, e.g. B. in the form of a burst at the beginning of the line, which indicates this increase in amplitude. During the reproduction, this identification signal reduces the amplitude, which is too large in the case of small color difference signals, to the original, correct value. Such a measure for better utilization of the transmission capacity for small signals is described in more detail in DE-OS 33 33 071.

Fig. 3 shows a circuit for the recording for the two variants according to Fig. 1 and Fig. 2. It is first described on the acquisition according to FIG. 1. In this type of recording, the two switches 2 , 3 are in the drawn position. The CVBS signal is split in the separator 4 into the luminance signal Y and the modulated color carrier F. Y reaches the linear adder stage 9 via the sub-de-emphasis stage 5 , the main de-emphasis stage 6 , the amplitude limiter 7 and the FM modulator 8 . The color carrier F passes over the bandpass 10 with a Durchlaßbe range of 4.43 + 0.6-0.8 MHz on the converter 11th In the synchronous separation stage 12 , the line synchronizing pulses are separated at the frequency fH and converted in the converter 13 to the mixed frequency f 3 , which reaches the other input of the converter 11 via the high-pass filter 14 . At the output of the converter 11 is the frequency-reduced color carrier Fm, which passes through the low-pass filter 15 and the switch 3 to the adder 9 . The output signal of the adder 9 according to FIG. 1a is passed via the amplifiers 16 , 17 to the heads K 1 with the small gap width of 0.2 μm.

The color difference signals RY, BY pass through the low-pass filter 18 with a cut-off frequency of approximately 2.15 MHz to stage 19 , which cause a clamping of the color difference signals and, if necessary, a simultaneous / sequential conversion. At the exit from level 19 , the color difference signals RY, BY are displayed sequentially. These pass through the pre-emphasis stage 20 , the amplitude limiter 21 , the FM modulator 22 and the amplifier 23 as color carriers Ft to the heads K 2 with the larger gap width of 0.4 to 0.45 μm. The sound carriers T 1 , T 2 can be recorded according to FIG. 1b.

In the second type of recording according to FIG. 2, the switches 2 , 3 are in the dashed position. The luminance signal Y is supplied via the low-pass filter 24 with a cut-off frequency of 5.0 MHz and processed in the same manner as in FIG. 1. The ink channel path 10 , 11 , 15 , 3 is now not fed with an ink carrier. The lower input of the adder 9 is grounded via the switch 3 . The color recording is now only in the manner described via path 19-23 with heads K 2 . In the now free frequency range of 0-1 MHz, the four FM sound carriers T 3 , T 4 , T 5 , T 6 are now recorded with the heads K 1 in the manner described. For this purpose, the two sound carriers T 1 , T 2 are fed to the converter 25 , which effects the described implementation of 1.4 MHz and 1.8 MHz on the sound carriers T 3- T 6 . The sound carriers T 3- T 6 obtained in this way pass through the bandpass filters 26 , 27 additively to the amplifiers 16 , 17 in such a way that the sound carriers T 5 and T 6 the amplifier 16 and thus the upper head K 1 and the sound carriers T 3 and T 4 the amplifier 17 and thus only the lower head K 1 are supplied. This recording of the sound carriers is only possible if the color carrier Fm is not recorded.

Fig. 4 shows the corresponding playback circuit. The sampled from the tape T passes over the image carrier B 1 traces of toggle the curser between the two heads K changeover switch 28 which serves to delay compensation stage 29, the amplitude limiter 30 to the FM demodulator 31st This delivers the demodulated luminance signal Y via the low-pass filter 32 , the de-emphasis stage 33 and the delay element 34 to the terminal 35 , at which Y is available for image reproduction. The ink carrier Fm reaches the converter 37 via the low pass 36 . The luminance signal Y passes from the terminal 35 to the synchronizing pulse separating stage 38 , which supplies line synchronizing pulses with the frequency fH to the converter 39 . The Mischträ ger f 3 passes through the low-pass filter 40 to the other input of the converter 37 , which again supplies the color carrier with the frequency f 1 at its output. This reaches the terminal 44 via the bandpass 41 , the transit time stage 42 and the changeover switch 43 in the fully extended position. In stage 45 , the CVBS signal is additionally generated from Y and F.

The ink carrier Ft is scanned with the heads K 2 from the deeper layer S 2 of the magnetic tape T and passes via the switch 60 which switches between the heads K 2 , the delay stage 46 serving for delay compensation, the amplitude limiter 47 to the FM demodulator 48 . This provides the two sequential color difference signals RY, BY, which pass through the low-pass filter 49 and the de-emphasis stage 50 to the circuit 51 . The circuit 51 includes, inter alia, a line delay line and a matrix and converts the sequential color difference signals back into simultaneous RGB signals, the synchronizing signal S and simultaneous color difference signals. For this purpose, the stage 51 is additionally supplied with the luminance signal Y from the terminal 35 .

In a recording shown in FIG. 2 without the color carrier Fm, the switch is turned over to the dotted line position 43rd The color carrier F at terminal 44 and the CVBS signal are then not available. The complete signal for the replay is still available, namely by Y at the terminal 35 and by the output signals of stage 51 . In this type of recording, the sound carriers T 3- T 6 are recorded according to FIG. 2a. These sound carriers pass through the low-pass filter 52 with a cut-off frequency of approximately 1.1 MHz to the converter 53 , which is fed by the converter 54 with the mixing frequencies f 6 , f 7 and the two sound carriers T 1 , T 2 at its outputs with 1.4 and 1.8 MHz. These pass through the bandpass 55 to the FM demodulator 56 , which again supplies the two audio signals NF 1 and NF 2 for L and R.

Claims (14)

1. Video recorder with improved color recording, in which a with the luminance signal (Y) modulated image carrier (B) with the first magnetic heads (K 1 ) narrow gap width is recorded in an upper layer (S 1 ) of the magnetic tape (T), characterized marked net that the color difference signals (RY, bY) zeilense quentiell through FM modulation of a carrier (Ft) having second magnetic heads (K 2) of larger gap width in a deeper layer (S 2) of the Magentbandes (T) are recorded. 2. Recorder according to claim 1, characterized in that the image carrier (B) is so broadband modulated that it takes up the entire available recording bandwidth of the upper layer (S 1 ) when dispensing with the recording of a color carrier (Fm). 3. Recorder according to claim 1, characterized in that the color carriers (Ft) are so broadband modulated that they occupy the entire available recording bandwidth of the deeper layer (S 2 ). 4. Recorder according to claim 3, characterized in that with sound signals frequency-modulated sound carrier (T) in the upper magnetic layer (S 1 ) below the Fre frequency spectrum of the image carrier (B) are recorded. 5. Recorder according to claim 4, characterized in that the frequencies of the sound carriers (T) from field to Field switched between different values and that each define 2 frequencies  The heads of a pair of heads are assigned to the heads of a pair of heads with different FM sound Signals are fed. 6. Recorder according to claim 1, characterized in that in the lower layer (S 2 ) additionally modulated te sound carriers (T 1 , T 2 ) are recorded in frequency division multiplex. 7. Recorder according to claim 1, characterized in that during playback a circuit ( 51 ) with a line delay line and a matrix is provided which converts the sequential color carriers (Ft) into simultaneous RGB signals and / or a CVBS signal . 8. Recorder according to claim 1, characterized in that in the upper magnetic layer (S 1 ) only the BA-Si signal without synchronizing signal and the synchronizing signal together with the color difference signals in the lower magnetic layer (S 2 ) is recorded. 9. Recorder according to claim 1, characterized in that when recording the amplitude of the color difference signals (R-Y, B-Y) is regulated so that the frequency stroke range (3.5-4.2 MHz) of the color carriers (Ft) always is fully utilized. 10. Recorder according to claim 9, characterized in that a Pilotsi indicating the change in amplitude gnal is recorded, which during playback a Reduction of the amplitude of the demodulated color diff caused reference signals to the original value.   11. Recorder according to claim 1, characterized in that in the upper magnetic layer (S 1 ) below the frequency spectrum of the modulated image carrier (B) additionally with the color difference signals quadra-modulated, modified color carrier (Fm) is recorded ( Fig. 1). 12. Recorder according to claim 11, characterized in that during playback in the event of a fault in the color carrier (Ft) from the deeper layer (S 2 ) of the modified color carrier (Fm) from the upper layer (S 1 ) as a substitute signal for the Image playback is used. 13. Recorder according to claim 1, characterized in that a recording of the color carrier (Ft) in the deeper layer (S 2 ) indicating the identification signal is recorded, which during playback an automatic switchover ( 43 ) of the color channel to the second heads (K 2 ) causes. 14. Recorder according to claim 13, characterized in that the identification signal by an additional modulation a recorded sound carrier (T) is formed.