DE4040280A1 - Video recorder with reduced cross=talk - records on two layers of magnetic tape by switching phase of frequency modulated carriers such that adjacent tracks have 180 deg. phase difference - Google Patents

Abstract

The video recorder uses one set of heads of narrow gap width to record a first signal (To) in the upper layer of a magnetic tape and heads having a larger gap width to record a second signal (Tu) in the lower layer of the tape. The first signal may be a carrier frequency modulated by a luminance signal (Y), the second signal being a carrier modulated by a sound or colour-difference signal. Two diagonal tracks are recorded in both magnetic layers of the tape using recording heads with different azimuth angles. The phase of the carrier recorded on one track is switched through 180 deg. w.r.t. the second track. ADVANTAGE - Reduced cross-talk between layers of magnetic tape.

Description

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

There are known VCRs with first heads narrow gap width of about 0.2 µm in an upper magnet layer of the tape a first signal and with a second magnet heads larger gap width of about 0.4-0.45 microns in one second, lower lying magnetic layer of the tape a two t signal is recorded. The first signal is e.g. B. a with the luminance signal Y frequency-modulated image carrier. The second signal contains e.g. B. with sound signals gated sound carrier or frequency mod with color difference signals gated ink carrier. When recording, the first with the second heads over the entire thickness of the magnet layer made recording at the subsequent opening drawing with the first heads in the upper magnetic layer deleted again. In this way it is possible within independent magnetic signals in a magnetic layer to record with a certain crosstalk attenuation. Be remains due to tolerances in the band and in the heads however, some crosstalk attenuation between the signals of the two magnetic layers. This can be annoying if it is completely different, independent of each other  Signals that have a low crosstalk causes interference during playback.

The invention has for its object the crosstalk between the signals of the two superimposed Ma to reduce the net layers of the tape.

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

The invention therefore consists in principle in that in each the phase of the two magnetic layers with the signal fre frequency-modulated carrier from helical track to helical track Is switched 180 °.

The offset position of the inclined traces of the two magnetic layers ten is therefore used to advantage with a simple Phase switching the crosstalk between the magnetic layer to reduce. The phase change can be done again again balanced by appropriate phase switch will be. Such a phase change compensation however, is not essential. The one at the re effective FM modulators only speak to the Frequency of the signal, but not depending on the phase. The at The phase change made during the recording thus interferes FM demodulation during playback is not.

Preferably, there is between in each of the two magnetic layers two inclined traces lying next to each other create a gap without recording, a so-called lawn is provided. Here the lawn of one layer lies approximately in the middle a trace of the other magnetic layer.

An embodiment of the invention will follow hand of the drawing explained. Show in it

Fig. 1 shows the arrangement of the tracks in the band,

Fig. 2 is a block diagram for the recording and

Fig. 3 shows the track pattern on the tape.

Fig. 1 shows a magnetic tape M two superposed magnetic layers S 1, S 2. In the upper magnetic layer S 1 , an image carrier is recorded with heads K 1 having a small gap width of 0.2 μm, which is frequency modulated with the luminance signal Y. Between each successive Schrägspu ren To 1 , To 2 , To 3 , a lawn Ro is provided, which has a width of about 4 microns. The phase of the frequency-modulated image carrier is switched from helical track To to helical track To by 180 °, as indicated by the symbols 0 ° and 180 °.

In the lower-lying magnetic layer S 2 with Magnetköp fen K 2 larger gap width of 0.4-0.45 µm, a color carrier is recorded, which is frequency-modulated from line to line alternately with two color difference signals RY and BY. The phase of the ink carrier is also switched from helical track Tu to helical track Tu by 180 °. A lawn Ru is also provided between the successive inclined tracks Tu. The geometric position of the tracks To and Tu on the magnetic tape M is such that the tracks To and Tu of the two magnetic layers S 1 , S 2 are laterally offset from one another by about half the track width. In each case one field R of one layer is approximately in the middle of the useful track of the other layer.

The crosstalk between the two layers S 1 , S 2 is indicated by the arrows in FIG. 1. It can be seen that each track in one layer receives approximately the same crosstalk from two tracks in the other layer. However, these two traces of the other layer always have a phase difference of 180 °. The crosstalk signals from the two tracks of the other layer thus cancel each other out. For example, half of the track Tu 1 in the track To 1 causes a crosstalk component with the phase 0 ° and half of the track Tu 2 in the track To 1 causes an equal cross-talk component with the phase of 180 °. The signal components arriving from track 1 and track 2 by crosstalk in track To 1 thus cancel each other out in track To 1 . The switching phase of the phase switching device, ie the assignment of the phase 0 ° or 180 ° to the tracks is arbitrary. If e.g. B. in Fig. 1 the track Tu 1 would have the phase 180 ° and the track To 2 the phase 0 °, the same effect occurs. The described compensation of the cross-talk also applies in the opposite direction from the layer S 1 to the layer S 2 , as indicated by the downward arrows. The phase switching thus reduces crosstalk between the image carrier in layer S 1 and the color carrier in layer S 2 .

In FIG. 2, the luminance signal Y passes through the low-pass filter 1 having a cutoff frequency of 6 MHz and the Preemphasisstufe 2 to the FM modulator 3. The image carrier B generated in the modulator 3 and frequency-modulated with Y passes through the amplitude limiter 4 and the amplifier 5 once directly and once via the 180 ° phase switch 6 to the switch 7 . The output of the switch 7 is connected to the heads K 1 , which record the image carrier B along the inclined tracks To in the upper layer S 1 of the magnetic tape M. The switch 7 is switched by the switching voltage Us between two successive tracks To.

In the same way, two color difference signals RY and BY line sequentially pass through the low-pass filter 1 a with a cut-off frequency of 1 MHz and the pre-emphasis stage 2 a on the FM modulator 3 a. The generated in the modulator 3 a, with RY and BY line sequentially frequency modulated color carrier F passes via the amplitude limiter 4 a and the amplifier 5 a once di rectly and once via the 180 ° phase switch 6 a to the inputs of the switch 7 a. The ink carrier at the output of the switch 7 a is recorded with the magnetic heads K 2 on the oblique tracks Tu of the lower magnetic layer S 2 of the tape M. The switch 7 a is also switched by the switching voltage Us between two successive helical tracks.

Fig. 3 shows the arrangement of the helical tracks To of the layer S 1 on the magnetic tape M. The spatial position of the helical tracks on the tape is such that the line synchronizing pulses of the signals from adjacent helical tracks lie directly next to one another. The line sync pulses are thus each on a line that extends perpendicular to the tracks, as indicated by the line Z. This position of the tracks on the tape can be achieved by a special geometric arrangement of the heads on the head drum and, if appropriate, by a delay in the signals supplied to the heads. The same arrangement for the tracks Tu in the lower magnetic layer S 2 .

During playback, phase rotators can be provided with which the phase change introduced during recording is compensated for. This compensation of the phase changeover is not absolutely necessary, however, if the FM demodulators which are effective during playback only respond to the frequency of the signal supplied, but not to the phase thereof. The recording in the two layers S 1 and S 2 takes place with different azimuth angles from track to track. As a result, the crosstalk between adjacent tracks is reduced in each case in a layer S 1 or S 2 . The azimuth angle is preferably ± 6 ° for the upper layer S1 and ± 30 ° for the lower layer S2. Instead of a frequency-modulated color carrier F with color difference signals, sound carriers frequency-modulated with sound signals, a color carrier quadrature-modulated with color difference signals, a PCM sound signal, a MAC signal or other signals can also be recorded in the lower layer S 2 .

Claims (6)

1. Video recorder with reduced crosstalk, in which in two superimposed magnetic layers (S 1 , S 2 ) of the tape (M) along helical tracks (To, Tu) with different signals, frequency-modulated carriers are recorded and the helical tracks of the two layers are located laterally are offset from one another, characterized in that in both magnetic layers (S 1 , S 2 ) the phase of the carrier is switched from inclined track (To, Tu) to inclined track by 180 °. 2. Recorder according to claim 1, characterized in that when playing back helical track to helical track switched phase rotators are provided, which at the Cancel the recorded phase change. 3. Recorder according to claim 1, characterized in that in both magnetic layers (S 1 , S 2 ) the recording is carried out with angle from helical track to helical track different azimuth. 4. Recorder according to claim 1, characterized in that a lawn (R) lies between each of two inclined tracks. 5. Recorder according to claim 4, characterized in that each the lawn (Ro) of a magnetic layer (To) in the middle of a track of the other magnetic layer (Tu) lies. 6. Recorder according to claim 1, characterized in that the heads (K 1 , K 2 ) are arranged geometrically on the head drum so that the line synchronizing pulses (Z) of the signals of adjacent inclined tracks are spatially side by side ( Fig. 3).