DE2042434B2 - SYSTEM FOR RECORDING AND REPLAYING A COLOR IMAGE SIGNAL ON A MEMORY ALONG A TRACK WITH ADJACENT TRACK SECTIONS - Google Patents

Description

8 System according to claim 2 or 3, characterized in that the demodulation of the color carrier (10 with a reference carrier with the converted frequency takes place during playback

9. System according to claim Ib, characterized in that during playback, the phase switch made during recording is canceled again by a corresponding reciprocal switchover.

It is known to represent an optical image electrical image signal. /.B. a television signal to record a recording medium so that ver different track sections of a continuous track lying next to each other. This is e.g. B. the case with oblique recording on a magnetic tape under certain Conditions or in the case of a round recording medium in which the track has a spiral shape gen history. The recording takes place by modulating a physical quantity of the carrier, z. B. magnetically, optically or mechanically in the form of elevations and depressions. It is known to make the recording in such a way that spatially identical locations of an image are assigned Track sections are next to each other. For example, the track sections for lines are more spatially equal Ordinal number for successive images or half images always spatially next to each other During a run the disc-shaped recording medium are z. B. these lines in the radial direction side by side and the line sync pulses each on a radius of the disk. This recording has the advantage that then, when the scanner sweeps over two tracks or changes between two tracks, no mention is made of them errors occur because the black and white Infor mation of a certain line does not usually differ significantly from picture to picture or from field to field changes.

If after this procedure a coded dye image signal is recorded, it has been found that there is interference in chrominance in the reproduced image appear. These interferences appear with an NTSC signal. with a SECAM signal, with one PAL signal and a trizeline sequential signal. The described recording method thus does not seem to be readily suitable for recording a color image signal.

The invention is based on the object described To further develop the system in such a way that the above-mentioned disturbances during playback are avoided.

This task is accomplished for the color picture signals of the different color television systems by the following Measures resolved:

a) In the case of an NTSC signal, the phase of the recorded color subcarrier is relative in every second line changed by 180 ° to the previous line, or the frequency of the color carrier is an integer Multiples of the line frequency implemented in such a way that the modulation phase for adjacent track sections is the same for the same color information.

b) In the case of a SECAM signal, the timing of the signal sequence in the individual fields is controlled so that the signals recorded in adjacent track sections represent the same color separation, and in the case of a signal in the form of tines Color carrier, the phase of the color carrier in each line is controlled so that the phase is the same for adjacent track sections

c) In the case of a PAL signal, the temporal position is the Signal sequence in each field controlled so that color carriers of the same PAL switching state are recorded in adjacent track sections, and the phase of the color subcarrier is controlled in each line so that the modulation phase is adjacent to each other

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is equal to.

d) In the case of a tri-line sequentially different color The color image signal showing extracts is di-; temporal Position of the signal sequence in each field is controlled in this way. that in adjacent track sections each, " because color signals representing the same color separation are recorded.

By the aforementioned, by "NTZ" 1962. Pages 644 to 649 known order of the Spurab sections in such a way that the line sync pulses and μ lines of the same ordinal number are next to each other, the problem underlying the invention is not achieved. With this arrangement 7 \ var one on the corresponding lines of successive images or fields lie next to one another. Therefore, the m frequency of the carrier modulated with the video signal in FM between adjacent Punk th adjacent track sections is approximately the same, so that when the scanner jumps between these track sections, the errors remain small. But ₍₁ which applies readily not for the enthai requested in the video signal color signals, namely due to the special whose construction of these signals. The invention has additionally applied so in this known system for recording a color image signal who ", the.

The invention is based on the following knowledge. All known color television signals have their own peculiarity. that they us.ind variously ^r of any parameters from line to line. With the NTSC color carrier _1S the phase of the color carrier is switched from line to line by 180 "relative to the line period (half-line offset). With the SECAM color carrier there is also a phase change between the lines according to a certain system. With color carrier i _{() of} the PAL signal there is a phase change due to the quarter line offset and the 25 Hz offset and also a change in the PAL switching status from line to line, i.e. the direction of rotation of the modulation. With a TRIPAL signal, the color signals represent different basic colors from line to line.

Since the number of lines in an image is not divisible by 2 and (with TRIPAL) not by 3, they are omitted different color signals on adjacent track sections in the above sense. If now the Scanner scans two track sections or changes between two track sections, color distortions occur because then a message or an alternating sampling of different color signals he follows. It became known that this is the cause of the color errors described.

The invention avoids this disadvantage in that similar color signals are recorded on adjacent track sections, for example the same phase relative to the Zeflenperkx'e. same basic color or same PAL switching status. If the scanner now scans two tracks at the same time or changes between tracks, the same type of color image signals are communicated, so that no significant disturbances occur in the reproduced image.

The invention is explained below with reference to the drawing. The figures show the mode of operation of the invention, namely

Fig. 1.2 for an NTSC signal Fig. 3, 4, 5 circuit examples for the solution according to

Hg.Z.

F i g. 6. 7. 8 door a SEC AM-Sipnal, Fig. 9. 10 for a PAL signal and Fig. II for a TRIPAL signal.

In Fig. I a modulated NTSC color carrier F is recorded on adjacent Spurab cuts 1, 2. The point 3 represents a certain point, e.g. B. the beginning of lines of the same ordinal number of consecutive images. Due to the half-line offset in the NTSC color carrier and the odd number of lines per image, the phase of the color carrier assigned to a certain th color is at these points from image to image, i.e. between the track sections 1, 2 different by 180 °. If now the color carrier in point 3 on sections I, 2 is modulated with the same signal (more like information content of successive images) and the scanner 4 sweeps over both track sections 1 by means of a sensor alignment, an averaging over the 180 ° oppositely directed color carriers / · ', And F ₁ instead. It can be seen that z. B. in the case when the same amount of signal is taken from both tracks, delete the color carriers. In other incorrect positions of the Abta star 4 phase errors occur in the scanned color carrier. which cause color defects.

According to FIG. 2, the half-line offset of the color subcarrier is canceled so that the color subcarriers / · ", and F _{2 have the} same phase, that is to say the signals on the two sections 1, 2 are similar in the above sense. It can be seen that the scanner 4 now finds two color carriers of the same phase when sweeping over both track sections I, and thus the described color distortion does not occur.

According to FIG. 3 the conversion of the color carrier F into the modified color carrier F _m suitable for recording takes place with a phase changeover 5. which is controlled by a half-line frequency switching voltage 6 and switches the phase of the color carrier in every second line by 180 " the phase change caused by half-line offset by 180 ° from line to line is canceled, the color carrier has the same phase as for a certain color at a certain location of a line from line to line and thus also for adjacent points of the track sections 1, 2 2. During playback, a corresponding feedback is provided during demodulation in order to establish the correct phase relationship between the modulated color carrier and the reference carrier used for demodulation. For example, the offset is reintroduced or the reference carrier is switched over according to FIG thus effective for recording and playback.

According to FIG. 4, the conversion from F to F _{n takes place} in a mixer 6. This is controlled by an oscillator 7, the frequency of which is so dimensioned and coupled to the line frequency f " by line synchronizing pulses 20 that the frequency of the color carrier F _{n is} an integral multiple of the line frequency. As a result, the condition according to FIG. 2 is also met. During playback, demodulation then takes place with a reference carrier of this new frequency. ι ο

In FIG. 5, the color carrier F is demodulated in a synchronous demodulator 9 controlled by a reference carrier oscillator 8. The two video-frequency color signals obtained (J and V are modulated in a modulator 10 onto a new color carrier generated in an oscillator 7. The oscillator 7 is again controlled by line synchronization pulses 20 and generates a color carrier with an integral multiple nf “of the line frequency.

In Fig. 6, in the case of a SECAM signal, adjacent Track sections 1, 2 similar FarbdifTerenzsignale, so z. B. R to Y or B up to Y video frequency or recorded as color subcarrier modulation. The scanner 4 therefore finds its way over two track sections 1, 2 or when changing between the track sections similar color difference signals so that no noticeable color tone errors occur.

7 shows a further condition which must be met in the case of a standardized SECAM color television signal. The signal already gives a specific frequency and the modulation phase to the line period. According to FIG. 7, the phase of the SECAM color subcarrier is switched between 0 and 3 <180 ° in certain lines according to the law shown. 7 shows that, for example, the color carriers in lines with the spatial ordinal number r between the fields 3 and 5 recorded on adjacent track sections have different phases. According to the invention, means are provided, for example according to FIG. 3, which convert the phase indicated by η in FIG. 7 into the phase 0 °. This switching can be controlled by the unmodulated color subcarrier oscillations sent at the beginning of each line, with frequency switched from line to line, or by the SECAM identification signal sent during the vertical blanking time.

Fig. 8 shows such a circuit. The SECAM color carrier F is a push-pull transformer 12 to a aas four diodes existing switch 13 trains leads to which a Phaseniimschaltung by means of a voltage applied to a terminal 14 switching voltage is possible the modified SECAM color carrier F _m ent of a terminal 15 via a transformer 16 - take μ. The switching voltage 17 shown applies z. B. for the temporally consecutive lines 1, 3, 5, 7, 9, 11 of the field 1. Each time the phase st, that is to say 180 ° nt, the switching voltage 17 has a positive value and switches the phase by 180 * m to 0. The modified SECAM color carrier F _m then always has the same phase for a bee color in adjacent points of adjacent track sections. In the case of color reproduction, reciprocal switching is only necessary if the reproduced signal is supposed to be compatible

In the case of the color subcarrier of the PAL color television signal , the quarter-line offset and 25 Hz offset of the color subcarrier are eliminated, as is the half-scale offset in the NTSC signal according to FIGS. This can be done again with one of the circuits according to FIGS. 3, 4, 5. It is then achieved that the color carrier for the modulation axis B to Y, that is to say that only with the color difference signal B. until Y modulated color carriers have the same phase at the same points on all lines. In the case of the PAL signal, according to the invention, the PAL switchover, that is to say the zei-Ienfrequente switchover of the R to Y axis, is taken into account.

This is explained with reference to FIGS. 9, 10. In FIG. 9 it is assumed that the quarter line offset and 25 Hz offset have already been canceled, for example with a circuit according to FIG. 4, indicated by F _n .

When the PAL signal was recorded, the color carriers recorded on adjacent track sections 1, 2 would then have the form F _m and F _n , these color carriers, for example, each referring to the beginning of the line. There are thus on adjacent track sections 1, 2 conjugate complex color carriers. If the scanner 4 now, for example, sweeps the track sections 1, 2 or changes between d'sen, an averaging over the color carriers F _m and F _n takes place according to FIG. 9, whereby in reality the color carrier F ₁ - is scanned. It can be seen that this is an out-of-phase color vehicle.

According to FIG. 10, according to the invention, PAL color carriers of the same PAL switching state, ie either only F _n or only F _n , are recorded on adjacent track sections 1, 2. If the scanner 4 now sweeps over both track sections 1, 2, it will find color carriers of the same phase with the same information content, so that the color falsification occurring in FIG. 9 does not occur. In the case of the PAL signal, three factors must be taken into account or compensated for, namely the quarter line offset, the 25 Hz offset and the PAL switching according to FIG. 9. It is also important here that the color carrier for the same hue is on adjacent points adjacent track sections has the same phase.

In Fig. 11 the invention for a line sequen tielles TRIPAL signal and a round recording medium (optical disc) is shown. The color signals R, G, B representing the three primary colors are recorded line by line on a spiral track 18 , with the track sections assigned to the lines opposite one another in the radial direction. The line synchronizing pulses of the signal gen lie in each case on radial lines 19, according to the invention ;, are next to each other in the radial direction Hege ligand track sections always color signals of the same color, eg R. G or B recorded. If the scanner 4 does not have the right radial position shown at 4 ', but the position 4 and thus sweeps over two track sections 1, 2, no errors worth mentioning arise because the color signals representing the same basic colors are recorded on these track sights. Even if the head 4 changes between two track sections 1, 2 as a result of a fluttering movement in the radial direction, no errors worth mentioning occur.

The assignment of the color image signals to the track sections according to the invention can also take place in that a specific time-shift is introduced into the color image signal. E.g., could be in Fig. 1 shows the modulated color carrier during duration

7 8

shift between the color image signal sequence and the

be, whereby the desired phase condition track sections can also be adjusted by a

according to IMg. 2 is reached. F.bcnso this Vcr control of the movement of the recording medium

Zößcrung with the SliCAM signal according to Fig.fi and are sufficient.

home PAL-Sigr.al shown in FIG. 9. 10 carried out advertising '■ The color image signal may, together with a

the. If e.g.

successive images are assigned and the various frequency positions. For example, on the scl- L \

Color carrier sequence / '' during the track section 2 next to a track modulated with two color difference signals.

assigned image delayed by one line duration ter color carrier of 500 kHz and one with the Lcucht- Π

the desired assignment is made according to frequency-modulated carriers in the stroke

Fig. 10 reached. Due to this time shift, recorded rich from 3 to 4MHz . The hearing

The assignment according to the invention can also be used in line-sequential processes.

color signals representing individual primary colors in which the luminance signal and coded color signal

can be achieved according to FIG. These temporal verals are recorded alternately line by line.

1 sheet of drawings

209535/514

Claims (7)

Patent claims: 1. System for recording and reproducing a color image signal on a memory along a lane with adjacent lanes; intersected, with spatially identical places in time track sections assigned to successive images lie next to one another, marked by the following measures: a) In the case of an NTSC signal, the phase of the recorded color carrier is changed by 180 ° relative to the previous line in every second line (level 5 in Fig. 3), or the frequency of the color carrier (fore IC * t Ollf * a 0 » ψ * · »· **% ϊ * ΚξψΛ ** 9 \ 7Mir« eUs »/ _ - * Vf ^ J-- Line frequency (f“) converted in such a way (Fig. 4 and n 5) adjacent track sections (1, 2) for the same color information is the same. b) With a SECAM signal, the timing of the signal sequence is in the individual fields controlled so that in each case the adjacent Track sections (1, 2) recorded Si gnaie (R to V. B to Y) the same color separation represent (Fig. 6). and in the case of a signal in the form of a color carrier, the phase of the color carrier is in each line is controlled so that the phase for adjacent Track sections (1, 2) is the same (Fig. 7. 8). c) In the case of a PAL signal, the temporal position is the signal sequence in each field is controlled in this way. that in adjacent track sections (I. 2) Color carrier with the same PAL switching status (F or F) are recorded, and the phase of the color carrier (F. F) is controlled in each line so that that the modulation phase in adjacent track sections (1, 2) for the same color information mation is the same (Fig. 9. 10). d) In the case of a color image signal representing different color separations in a sequence of three lines, the timing of the signal sequence in each field controlled so that in adjacent track sections (1, 2) each showing the same color separation representing color signals (R or G or B) are drawn (Fig. 11). 2. S_ \ star according to claim I a. characterized in that the frequency conversion is carried out by mixing the color carrier (F) with a voltage coupled to the line frequency (FIG. 4). 3. System according to claim Ia. thus known h> draws that the frequency conversion by demodulating the color carrier and subsequent new modulation on a color carrier with an integer multiple (nf ") of the line frequency (f") takes place (Fig. 5). " 4. System according to claim la, b or c. characterized in that the control of the Phase takes place by phase switch switched between the lines (Fig. 3. 8). 5. System, and is characterized according to claim 1. characterized marked _(that the temporal position of the signal sequence is provided by a switched into the signal path delay. 6. System according to claim 5, characterized in that the signal sequence during every two & i tone image is delayed by one line. 7 System according to claim la, characterized in that in the reproduction in the path of the modulated color carrier or of the reference carrier serving for demodulation, a 180 ° phase rotator is switched on in every second line