DE2134556A1 - METHOD OF RECORDING AN IMAGE SIGNAL - Google Patents

Description

Method of recording an image signal When recording an image signal, e.g. a television signal, on a record carrier, e.g. an optical disc, it is known to transmit the signal in the form of an FM modulated carrier to record. In the case of many recording media, there are individual track sections very close to each other, e.g. on the spiral track of an optical disc. With such closely adjacent track sections can have the signals lying next to each other Track sections take effect simultaneously when scanning. If, for example, a spiral track of the scanner jumps back and forth in the radial direction, so will the signal from different track sections is evaluated alternately.

With a wider scanner, it is possible that the scanner also the signal that scans the track section lying next to the track section being scanned. The recording process can also result in a certain amalgamation of the information adjacent track sections occur, e.g. during a pressing process of a Image plate. In all of these cases, there is an overlap during the scan of the signals of adjacent track sections, causing interference in the reproduced Image can arise.

To reduce these disturbances it is known to work side by side lying track sections to record signals that are spatially identical of a scanned image. When the optical disk are on in the radial direction adjacent track sections each have lines of the same Ordinal number recorded, the line sync pulses on radial lines lie. If in such a system the scanner in the radial direction in the next If the track section jumps, it will find the same pixel of the next image there before, so that by jumping only an imperceptible, dependent on the sequence of movements Adulteration occurs.

When recording a frequency-modulated carrier it is too known, the frequency of the carrier is an integral multiple of the line frequency to make so that recorded on the adjacent track sections with the same Signal maxima and minima of the carrier oscillation lie side by side.

It has been shown that despite the known measures, through the crosstalk between two track sections interference between the recorded FM carriers appear. While it is known to interfere by limiting the FM carrier scanned to reduce. In many cases, however, this measure is not sufficient.

The invention is based on the object of a recording method to create in which the mentioned remaining disturbances in the scanning avoided will.

This object is achieved by the invention described in claim 1 solved. Further developments of the invention are given in the subclaims.

The inventive scheme is achieved that between æ adjacent track sections with the same signal a flawless one There is agreement in frequency and phase of the two recorded FM carriers. When the scanner then jumps between these track sections or signal components scans both track sections simultaneously or the signals of the track sections have already merged slightly with each other through the recording or also if any other crosstalk takes place between these signals, that remains Occurring disturbance due to the correspondence of frequency and phase is low.

The regulation is preferably carried out during the line blanking time, e.g. the black shoulder or the sync pulse. The constant signal value is preferred the black level or an ultra black level. The control voltage is thereby via a Memory circuit out, which ensures that the input of the FM modulator effective control voltage during the periodic period mentioned with lower Time constant becomes fully effective or can quickly adopt a new value, afterwards, e.g.

during line trace, retains this value. This can be done with, for example a clamp circuit that holds the image signal during the periodic period stuck to the value of the control voltage. The regulation is achieved, for example, by that the modulated FM carrier with a comparison oscillation, which the constant Has a frequency corresponding to the signal value and a phase constant to the line period, is compared and the manipulated variable obtained therefrom during the periodic period serves as control voltage.

The invention is explained below with reference to the drawing.

FIG. 1 shows curves to explain the mode of operation, FIG. 2 shows a block diagram and FIG. 3 shows a tried and tested exemplary embodiment of the Invention.

Fig. 1 shows two track sections 1.2, which in a spiral Track of an optical disk lie next to each other in the radial direction. At location X of the track sections 1, 2 begins each line of a recorded image. On the track section 1, an FM carrier 3 is recorded, and an FM carrier 4 is recorded on the track section 2. During the period dt, which corresponds to the black shoulder, the signals have a constant value, namely the black level. According to the invention is by a triggered by a key pulse 16 control achieved that the carrier 3.4 during of the period bt up-constant, corresponding to the signal value during the period lt Frequency and also set to constant phase relative to the line period are. This is shown in FIG. 1 by the phase PO at location X. Through this regulation, those with a memory circuit described in Fig. 2 during the line trace time is maintained, the carriers recorded side by side have 3,4 while the line trace time following the period At for the same modulated Signal the same frequency and phase to the line period. If now a scanner 6 signal components running in the direction 5 over the track sections 1, 2 scans from both track sections 1,2, it finds carriers of the same frequency and same phase. As a result, the disturbances described at the beginning are caused by interference largely avoided.

FIG. 2 shows an embodiment of the control circuit according to FIG. 1.

A luminance signal Y to be recorded is supplied by a terminal 8 fed via an adder 9 to a modulation input 10 of an FN nodulator 11, at its output via an amplitude limiter 12 with the signal Y in FM-modulated carrier F supplies, which is recorded in a known manner. the The frequency of the carrier F is therefore always equal to the instantaneous value of the signal Y. According to the invention becomes the modulated Carrier F in a discriminator 13 with a Comparison oscillation fO compared. This comparison oscillation is in an oscillator 14 generated by a terminal 24 with line sync pulses 25 of the signal Y is controlled. The line sync pulses 25 are derived from the signal Y or taken from a clock generator. The pulses 25 generate a comparison oscillation in the oscillator 14 f0 with the frequency corresponding to the signal value of Y during the period At and a constant phase to the line period. The oscillator 14 can be a start-stop oscillator or be a driving oscillator, which is always with the line sync pulse 25 the same phase is started. In the discriminator 13 is a control voltage UR obtained via a filter element 17, a gate 18 and a memory circuit Input of the adder 9 is fed. The gate 18 is activated by the key pulse 16 controlled permeable during the period bt. The memory circuit 21 is like this formed that in it the control voltage occurring at the output of gate 18 with a time constant that is shorter than the line return time and is then retained during the line trace time. At the output of the circuit 21, therefore, a control voltage arises which is fed to the FM modulator 11 during the time adjusts to the correct frequency and phase. This control voltage is during the return time is always corrected quickly and then remains during the return time obtain. In the adder 9, this control voltage is the signal Y, which is the frequency modulation causes, superimposed. The circuit 21 may, for example, be a clamp circuit in which the signal Y during the duration of the pulse 16 to the value of during this time existing control voltage is clamped.

Fig. 3 shows a practical embodiment of the circuit according to 2. The circuit 21 used is a clamping circuit which is formed by a capacitor 22, the gate 18 and the low-resistance output of the sieve member 17 is formed. While the Duration of the pulse 16 is the base of the transistor 23 with the permeable controlled gate 18 to the standing at the exit of the sieve member 17 Brought control voltage by the capacitor 22 through the permeable gate 18 and the low-resistance output of the filter element 17 is charged to a corresponding voltage will. The input of the transistor 23 has a high resistance. Through this clamping circuit it is achieved that the control voltage which reaches the base of the transistor 23 during the period is retained during the following line trace time and thus the frequency and Phase has its correct core value. This tension is then superimposed by that of signal Y coming from terminal 8 and modulates carrier F.

The transistor 23 serves as the adding stage according to FIG. 2 here the basis of which both the control voltage and the signal Y arrive. The FM modulator 11 is designed as a multivibrator, the diodes 19, 20 for limiting the amplitude serve for the carrier oscillation F. The regulation described does not need to be constant Phase to be done. It can also be done so that the phase between each other lying track sections by 1800 is different. Then it would turn to one Crosstalk decrease the amplitude of the scanned carrier while increasing the frequency remains unadulterated and interference does not occur either.

Claims (15)

Claims Method for recording an image signal on a track of a Recording medium in which adjacent track sections are spatially the same Make the picture correspond and the signal in the form of a frequency modulated Carrier is recorded, in particular for an optical disc, characterized in that that the carrier (F) in each case during a periodically recurring, a constant Signal value of the corresponding period (a t) at constant frequency and defined Phase to line period is regulated. 2. The method according to claim 1, characterized in that the regulation occurs during the line blanking time. 3. The method according to claim 2, characterized in that the control while the black schoolers takes place. 4. The method according to claim 1, characterized in that the constant Signal value is the black value or an ultra-black value. 5. The method according to claim 1, characterized in that the control voltage (UR) is passed through a memory circuit (21), which allows a quick change of the Control voltage during the periodic period (bt) enables and the control voltage sustains during the following period. 6. The method according to claim 5, characterized in that the memory circuit a clamping circuit (22,18) which during the periodic period (lot) the Image signal (Y) stuck to the value of the control voltage. 7. The method according to claim 1, characterized in that the defined Phase is constant. 8. The method according to claim 1, characterized in that the defined Phase from line to line or between adjacent track sections 180 ° is different. 9. Circuit for a method according to claim 1, characterized in that that the carrier (F) and a comparison oscillation (fO) with constant phase to the line period a phase comparison stage (13) are fed, the periodic during the recurring period of time (d t) occurring output voltage as control voltage (UR) to a modulation input (10) of the FM modulator (11) generating the carrier (F) is created. 10.Schaltung according to claim 7, characterized in that the image signal (Y) and the control voltage (UR) to the same modulation input (10) of the FM modulator (11) are applied. -11.Schaltung according to claim 7, characterized in that the comparison oscillation (fo) is obtained from the line sync pulse (25). ^ Circuit according to claim 7, characterized in that the comparison oscillation (fO) is obtained in an oscillator (14), each by the line sync pulse (15) is started with a constant phase. -3Circuit according to Claim 7, characterized in that the comparison oscillation is taken from a clock. 4.Schaltung according to claim 7, characterized in that the comparison oscillation the line sync pulse sfol ge is won by frequency multiplication. 15. Record carrier for a method according to claim 1, characterized characterized in that for adjacent track sections and the same signal value the recorded carrier has the same frequency urride-defined phase to the line period Has.