DE4016397A1 - VIDEO RECORDER WITH IMPROVED COLOR RECORDING - Google Patents

Abstract

In a VHS or S-VHS video recorder the colour signals are recorded with the "colour under" colour substrate only over a restricted bandwidth of some 0.5 MHz. It is the purpose of the invention to facilitate high-grade simultaneous recording of the RGB signals. Each video head (K1, K2) is replaced by two heads (K1a, K1b, K2a) of half track width (B/2) and the RGB signals are recorded by these heads in an upper (S1) and a lower layer (S2) of the magnetic tape (T). Especially for an S-VHS video recorder for the high-grade recording of D2-MAC signals.

Description

The invention relates to a video recorder according to the Preamble of claim 1. Such a video recorder is a so-called HiFi-VHS or HiFi-S-VHS video recorder with a high quality recording of the audio signals in HiFi Quality known. Such a video recorder has one increased bandwidth of the recorded luminance signal from about 5 to 5.6 MHz and a recording of the sound signals in HiFi quality. The color signals, however, are below the Frequency spectrum of the modulated with the luminance signal Image carrier with a reduced color frequency ger, also called "color under", recorded. This kind recording allows only a range of color si signals of about 0.5 MHz. The color rendering is therefore important Sharpness and signal-to-noise ratio compared to the luminous density tesignal relatively unsatisfactory.

When recording a high-quality D2-MAC signal this signal is first decoded, re-encoded in PAL and in be recorded in the manner described. With this type The quality characteristics therefore also go into the recording of the D2-MAC signal is steeply lost again. Would be optimal a simultaneous broadband recording of the RGB signals that are ultimately required for image reproduction will. However, such a record is with a  Video recorders of the type described are not readily possible Lich.

The invention has for its object a videore train the corder so that the RGB signals simultaneously with egg sufficient bandwidth for optimal playback can be drawn.

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 Auftei development of a helical track with a track width of about 50 µm two tracks half the track width of about 25 µm is considered Lich the recording quality and the feasibility of appropriate heads possible. Such a record with half the track width is used with video recorders Long game operation, so-called "long play", with separate Heads already made. In the invention, this is now possible exploited to use along a previous track a width of about 50 µm by halving the track width with two heads two independent signals with vol bandwidth. The fact is thereby revealed uses that for the recording of the B signal a lower Bandwidth of about 3 MHz is sufficient. This is because this range is sufficient for color rendering anyway and when forming Y from RGB, the B signal anyway is only involved with 10%. The lack of frequency range in the B signal of about 3 to 6 MHz can therefore be in the formation of Y without any quality disadvantages due to the corresponding proportions be replaced from the RG signals.

The solution according to the invention ensures that, for. B. a D2-MAC signal can be recorded with full quality  can and thus the special quality features of this Si gnales are not lost during recording. The recor which can be done without complex decoding and matrix circuits indirectly deliver the RGB signal at its output, which for high-quality image reproduction is preferred. The solution according to the invention does not require an increase in the tape consumption and also no reduction in the playing time of a given band. By recording the RGB signals eliminates the need for a quadrature modulated color carrier (color under). The featured for this seen frequency range below the frequency range of modulated image carrier can therefore be fre for recording Frequency-modulated sound carrier for a so-called hi-fi sound be exploited. Alternatively, the frequency range of the modulated image carrier down to low frequencies, that is to extend into the color under area, what a further increase in the bandwidth of the recorded Y signal causes.

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

Fig. 1 frequency spectra for explaining the recording according to the invention,

Fig. 2 is a block diagram for the recording,

Fig. 3 is a block diagram for the playback and

Fig. 4 frequency spectra of the baseband signals R, G, B.

Referring to FIG. 1, the R signal is less microns in the gap width of about 0.2 in the top layer S 1 of the magnetic tape T recorded by frequency modulation ei nes image carrier with a frequency deviation of 5.4 to 7 MHz with heads K 1 a. The heads K 1 a have compared to previous heads with a track width of 49 µm a halved track width B / 2 of 24.5 µm. Below the frequency spectrum of the image carrier, a frequency-modulated sound carrier T 1 is recorded with a frequency of 0.8 MHz ± 200 kHz. Half of the track with the width B written in previous recorders thus remains free when the signal R is recorded. In the same way, the G signal is drawn with heads K 1 b with the track width B / 2 on, specifically in the track width B / 2 that is left free with the R signal. Below the frequency spectrum of the image carrier modulated with G, a sound carrier T 2 is recorded with a frequency of 0.4 MHz ± 200 kHz. T 1 contains the sound signal of the right channel and T 2 the sound signal of the left channel of a stereo signal. The frequency difference between T 1 and T 2 has the purpose of allowing a frequency-selective separation of these sound carriers and to achieve a high crosstalk attenuation.

Referring to FIG. 1c more magnetic heads K 2 are provided with a larger gap width of 0.4 to 0.45 microns provided. Due to the larger gap width, this causes a recording in the deeper layer S 2 of the magnetic tape T. With the heads K 2 , the B signal is also recorded by frequency modulation of an image carrier, which has a static frequency swing of 3.5 to 4.2 MHz has a frequency range of about 1.2 to 4.5 MHz. The recording bandwidth of the B-Si signal is approximately 2.65 MHz. A division of the heads K 2 into two heads half the track width B / 2 is not necessary if only the B signal is recorded with K 2 . However, the heads K 2 , like the heads K 1, can also be divided into two heads of half the track width. Then in the deeper ren layer S 2 in addition to the B signal in the frequency range from 1.2 MHz to 4.5 MHz, other signals z. B. in the form of two frequency-modulated sound carriers and / or an Au dio PCM signal with DQPSK modulation. The R, G signals are recorded with a bandwidth of approximately 5.6 MHz and the B signal with a bandwidth of 2.65 MHz.

In the receiving circuit of FIG. 2 passes the R signal with the synchronous signal S through the low-pass filter 1 having a cutoff frequency of 5.6 MHz, the sub-Preemphasisstufe 2, the Ampli tudenbegrenzer 3, the FM-modulator 4 and the Aufnahmeverstär ker 5 on the two heads K 1 a, each with half the track width B / 2 . The two heads K 1 a have opposite azimuth angles of + 6 ° and -6 °. The signal G + S reaches the heads K 1 b via a completely equivalent path 1 a, 2 a, 3 a, 4 a, 5 a. The heads K 1 b are spatially offset relative to the heads K 1 a on the head drum so that they write the other track with the track width B / 2 according to FIG. 1 b, which were not written by the heads K 1 a with the signal R. . The signal B + S ge reaches the low-pass filter 6 with a cut-off frequency of 2.8 MHz, the pre-emphasis stage 7 , the amplitude limiter 8 , the FM modulator 9 and the amplifier 10 on the heads 2 a. These heads record the signal B + S according to FIG. 1c on half the track width B / 2 in the deeper magnetic layer S 2 .

A sound signal NF 1 arrives via the interference suppression circuit 11 in the form of a Dolby or Highcom circuit, the pre-emphasis stage 12 , the amplitude limiter 13 , the FM modulator 14 and the low-pass filter 15 in the form of the sound carrier T 1 on the adder stage 16 . A second sound signal NF 2 reaches the adder 16 via the same path as the sound carrier T 2 . The sum T 1 + T 2 from the output of the adder 16 passes through the amplifier 17 to the heads K 2 b, with which the sound carriers T 1 , T 2 are recorded on the track width B / 2 not described by B.

In Fig. 2, therefore, the recording of the sound carrier T 1, T 2 of the variant 1a is carried out according to FIG. 1c and not shown in FIG., B. The recording of the signals with K 2 a and K 2 b takes place in each case with a track width of approx. B / 2 = 22 µm with an intermediate space, a so-called lawn, of approximately 2.5 µm between the tracks. This lawn prevents crosstalk between the signals in the two adjacent tracks with B / 2 each. The two heads K 2 a for the half track width in the adjacent tracks have an azimuth angle of + 30 ° and -30 °.

In the playback circuit according to FIG. 3, the signal according to FIG. 1a arrives from the heads K 1 a via the head switch 18 , the delay stage 19 , the amplitude limiter 20 , the FM de-modulator 21 , the low-pass filter 22 with a cut-off frequency of 6 MHz and the de-emphasis stage 23 as signal R to the terminal 24 . The G signal is obtained at terminal 24 a via an identical path 18 a, 19 a, 20 a, 21 a, 22 a, 23 a.

The heads K 2 a supply of FIG. 1c over the head changeover switch 25, the run-time stage 26, the limiter 27, the FM Demodula gate 28, the low-pass filter 29 having a cutoff frequency of 2.7 MHz and the Deemphasisstufe 30 at the terminal 31 again the B signal. The RGB signals are thus simultaneously available at terminals 24 , 24 a and 31 . The sound carrier T 1 , which is recorded spatially offset to B with the heads K 2 b, reaches ge via the head switch 32 , the bandpass filter 33 with a pass band of 1.4 MHz ± 200 kHz, the amplitude limiter zer 34 , the FM Demodulator 35 , the de-emphasis stage 36 and the interference suppression circuit 37 on the terminal 38 , at which the audio signal NF 1 is available. The audio signal NF 2 is obtained at terminal 38 a via the identical route 33 a, 34 a, 35 a, 36 a, 37 a.

In Fig. 3, the RG signals have the full bandwidth of about 5.6 MHz, while the B signal has a reduced bandwidth of about 2.8 MHz. For the color channel, e.g. B. the extraction of the modulated color carrier from RGB anyway only the low bandwidth of 2.8 MHz is required, so that the lower bandwidth of B is irrelevant. When forming Y from RGB, however, signal B would not have the bandwidth required per se.

Fig. 4 shows the frequency spectra of the baseband signals R, G, B. R and G have the full bandwidth of about 5.6 MHz. B only has the narrow bandwidth of 2.8 MHz. The missing frequency range from 2.8 MHz to 5.6 MHz in B can be replaced by appropriate signal components from R and G, e.g. B. from the mean of R and G. This is indicated by the designation (a + b) / 2. When recovering the broadband Y signal, there is no noticeable disadvantage due to the reduced bandwidth of B, because B after the equation
Y = 0.59G + 0.3R + 0.11B
is only involved in Y with 11% anyway.

It is also possible, according to Fig. 1a, b each to divide a track with the conventional width B into three tracks, each with the width B / 3 and these three equivalent parallel tracks, each with B / 3, the three color signals RGB simultaneously with full Record a bandwidth of 5.6 MHz.

Claims (8)

1. Video recorder with improved color recording, in which an image carrier modulated with the image signal with video heads (K 1 ) with a small gap width in an upper magnetic layer (S 1 ) and further signals with second magnetic heads (K 2 ) with a larger gap width in a lower layer (S 2 ) recorded in parallel tracks of the magnetic tape (T), characterized in that one head (K 1 , K 2 ) is replaced by two heads (K 1 a, b; K 2 a, b) half the track width and the RGB signals are recorded simultaneously with these heads. 2. Recorder according to claim 1, characterized in that the R signal and the G signal with the first heads (K 1 a, b) half the track width (B / 2 ) in the upper layer (S 1 ) and the B -Signal the second heads (K 2 a, b) are recorded in the lower layer (S 2 ). 3. Recorder according to claim 1, characterized in that when reproducing in the formation of the Leuchtsi gnals (Y) from the RGB signals the upper missing Frequency range in the B signal by the corresponding Shares from the RG signals is replaced. 4. Recorder according to claim 1, characterized in that the two heads that belong together hal are formed over a track width by a combination head. 5. Recorder according to claim 1, characterized in that the two heads (K 1 a, b; K 2 a, b) are geometrically offset from one another in the track direction by the length of two recorded television lines. 6. Recorder according to claim 1, characterized in that the two heads (K 1 a, K 1 b) have oppositely directed azimuth angles. 7. Recorder according to claim 1, characterized in that with the first heads (K 1 a, b) in the upper layer (S 1 ) in the frequency range below the modu lated image carrier with NF sound signals (NF 1 , NF 2 ) fre frequency modulated Sound carriers (T 1 , T 2 ) who recorded the. 8. Recorder according to claim 1, characterized in that the heads (K 1 a, b; K 2 a, b) half the track width (B / 2 ) for long-term operation with half the tape longitudinal speed are provided.