DE2549839C3 - Device in a video record player for correcting speed and phase errors in the signal being played back - Google Patents

Description

The invention relates to a device according to the preamble of claim 1.

There is a playback system for optical disks in which there is between a stylus and the optical disk Measured changes in capacitance can be sensed to the information imprinted in the spiral groove of the disk to regain. Here is a composite television signal, which changes over time image signals and contains regularly recurring sync signals, in the form of geometric changes in a spiral groove recorded on the surface of the disk. The & 5 plate surface can be a conductive material with a overlying thin coating of dielectric material included. One on the stylus Metal electrode b'ldct together with the conductive one

Material and the dielectric coating a capacitor. The capacity fluctuations this Capacitor, which is characterized by the changes in geometry characteristic of the recorded signal in the Spiral groove will be felt and decoded to to obtain an output signal with television information. Such a capacitive optical disc system is described in detail in US-PS 38 42 194.

The signal information received from the optical disc all speed and phase errors must be converted exactly into a relatively shake-free color image in the recovered television information. That from the rotating Composite television signals recovered from optical disc may be subject to speed errors, for example as a result of warping of the disk or eccentricities of those storing the information Spiral groove in relation to the center hole of the plate. Such eccentricities or distortions lead to the fact that the signal sensed by an assigned signal scanner alternately with a faster and slower one Speed is received than it was recorded. To compensate for such alternating For speed errors, an electromechanical device can be used to determine the location of the The stylus steepens depending on the speed errors. An electromechanical device of this type, which can be described as an "arm extender" contain a transducer mechanically coupled to the stylus. By applying this Transducer with appropriate electrical signals can make the stylus in line with the speed errors be moved along the spiral. A typical arm extender is described in US Pat. No. 3,711,641.

In the previous playback devices for video disks, the arm extensor was controlled by clock signals such. B. Vertical or horizontal sync pulses controlled. The use of such sync pulses requires however, separate and additional circuitry to control the leading edges of these pulses stabilize. When using the sync signals you also need relatively complex circuits to to prevent incorrect signals from being generated by interference pulses if possible. The influence of Interference pulses or unstable edges of the clock signals can namely wrong control signals for the arm extension converter cause what is very annoying in the reproduced picture.

The arm extension transducer is also generally capacitively coupled to the associated control circuit, to prevent excessive transformer currents at very low frequencies. Such a capacitive one However, coupling leads to phase shifts in the control of the arm extensor and thus to a Limitation of the response frequency.

The present invention is based on the object of providing a device of the type mentioned at the beginning to the effect that the control of the arm extensor can be simplified and also Phase errors in the received chrominance carrier signal can be corrected.

This object is achieved in a device of the type mentioned according to the invention by characterizing features of claim 1 solved.

The subclaims relate to further developments and advantageous configurations of the invention.

The device according to the invention is characterized by a simple structure and a high correction capability out.

In the following, exemplary embodiments of the invention are described in more detail with reference to the drawing explained; it shows

F i g. 1 shows a block diagram of a circuit arrangement for phase stabilization of a color carrier signal and to control an arm extension converter,

F i g. 2 shows a block diagram of a control circuit for the arm extension converter according to one embodiment the invention,

3 shows a more detailed circuit diagram an embodiment of the invention,

F i g. 4a to 4d frequency responses (transmission functions) of circuit arrangements in the devices according to FIG. 2 and 3 and

F i g. 5 is a circuit diagram of a voltage-controlled oscillator which is used in the devices according to FIG. 1 and 2 can be used.

The present invention can be applied to optical disk players that incorporate a stylus, with one arrangement for decoding the composite television signal played back from a rotating video disc contains. The decoded signals are in a superposition arrangement with signals from a voltage-controlled oscillator superimposed to convert the television signal mixture in terms of frequency. A reference oscillator provides signals with essentially the same frequency as the color sync pulse in the converted signal, generated from the signals from the Überlagungsancrdiiung and the Signals from the reference oscillator will correspond to the phase difference between these two signals Signal generated. This phase difference signal is fed to the voltage controlled oscillator in order to generate the To influence the superposition frequency of the superposition arrangement that the frequency of the converted Ink carrier is kept relatively stable. A transducer or arm extension is coupled to the stylus, which adjusts the needle depending on the difference signals along the plate groove Control circuitry for the arm extensor can be DC coupled and that recorded on the optical disc Use color sync pulse as speed reference signal. It preferably contains a first Filter circuit to which the differential signals from the phase comparator are fed and which the low-frequency Part of these signals with a relatively high gain is the electrical signal input of the arm extension transducer feeds.

The signals appearing at the output of the first filter circuit can also be sent to a second filter circuit are supplied, which is coupled to the superposition arrangement and an increase in the amplitude of the This arrangement causes the difference signal supplied at frequencies that differ from the rotational frequency differ from the optical disk.

In Fig. 1, a video disk player 10 is shown on which is an optical disc 12 is attached to a scanning arm 40 belonging to the disc player Stylus provided, which is not shown in the drawing. The ones removed from the scanning arm 14 Signals are sent to a push-pull modulator. The output of the modulator 18 is with a Low pass filter 20 connected. The signals delivered by the filter are sent to a phase detector supplied, which also has signals from a reference oscillator 24 and from a color sync pulse

Tactile line 26 receives. The signals supplied by the phase detector 22 are voltage-controlled Given oscillator 40, which is preferably a voltage controlled crystal oscillator, and signals to the modulator 18 supplies. The detector 22 also supplies via a frequency compensating network (frequency compensator 17) and an amplifier 28 signals to an electromechanical arm extension transducer 34. The transducer 34 is mechanically coupled to the scanning needle located in the scanning arm 14. The one at the exit of the filter 20 appearing frequency-converted signals are transmitted via a transcoder (transcoder 44) coupled to a television receiver 46, where they can be played back.

In the operation of the arrangement described above, the optical disc 12 becomes a disc player on one 10 belonging turntable rotated. For the purpose of explanation it is assumed that the center hole of the Disk is not centered with respect to the spiral recording groove of the disk. The one from the plate derived signal information is thus subject to changes in speed when the disk turns.

The scanning needle located in the scanning arm 14 feels the changes in capacitance that occur as a result of the recorded Topography in the spiral groove of the plate results and couples these changes in capacitance to an im Arm 14 arranged pickup circuit (not shown). The pickup circuit within the arm 14 converts the capacity fluctuations into electrical signal changes, which are then transmitted to the FM demodulator 16 are given. The demodulator 16 extracts from the FM signals supplied by the arm 14 recorded composite television signal. This composite television signal recorded on the optical disc In the present case, I have a format with a so-called »stored ink carrier«. With this one Format, the components of the luminance signal occupy a wide frequency band of around 3 MHz Bandwidth, while the components of the chrominance signal form an interleaved narrow frequency band occupy. The chrominance signal has the form of 1/2 MHz wide sidebands of a 1.53 MHz color carrier, the occupy essentially the middle part of the broad band of luminance components. Furthermore are Color sync signals are available, each in the form of a reference oscillation pulse on the rear Black shoulder of the horizontal sync signals are located.

The signals generated by the demodulator 16 are applied to a push-pull modulator 18. This can be a unilaterally symmetrical modulator whose input part is symmetrical. By using a push-pull modulator, the baseband picture modulation component in the modulator output signal is practically suppressed. Suppression of the baseband signal simplifies the filtering of the modulator output signal in order to recover essentially only the frequency-converted television signal. The television signals fed to the modulator 18 are shifted or converted in frequency with the aid of the signals coming from the voltage-controlled crystal oscillator 40. The oscillator 40 supplies signals of essentially 5.11 MHz. By superimposing these oscillator signals with the television signal coming from the demodulator 16, a frequency-converted television signal with components in the upper and lower sideband 5.11 MHz on both sides is obtained. The color carrier, which was 1.53 MHz in the output signal of the demodulator 16, is now shifted to 3.58 MHz in the lower sideband of the frequency-converted television signal. A low-pass filter 20 with a pass bandwidth of approximately 8 MHz allows essentially only the first modulation product of the modulator 18 through, ie the sidebands on each side of a carrier lying at 5.11 MHz.
The frequency-converted signals from the output of the

Filters 20 are coupled to phase detector 22. The phase detector 22 samples the signals coming from the low-pass filter 20 with the aid of color sync pulse sampling signals, which are supplied via line 26 / ground. These tactile signals follow the horizontal sync pulses, which have been decoded by a circuit arrangement (not shown). The inside of the Phase detector 22 sampled video signals are compared with signals from the reference oscillator 24. the Reference oscillator 24 is a relatively stable oscillator that provides signals at 3.58 MHz and A resulting difference signal, which is the phase difference between the signals coming from the oscillator 24 and the color sync signal in the lower sideband of the frequency-converted Indicates television signal and appears at the output of the phase detector 22, is on the Frequency control input of the voltage controlled crystal oscillator 40 given. The oscillator 40 changes its frequency corresponds to the supplied difference signal and acts in the sense of a reduction this difference signal by changing the amount of frequency by which the composite television signal is at its implementation is postponed. A voltage controlled one suitable for use as the oscillator 40 Crystal oscillator is shown in Fig.5. The applied difference signal ensures that the The frequency of the oscillator 40 "trembles" to the same extent as the signal picked up from the plate 12. The The resulting frequency-converted video signal at the output of the modulator 18 thus has a frequency-stabilized one Color carrier that oscillates in a phase-locked manner with the reference oscillator 24.

A stabilization of the color carrier signal is necessary so that the colors of the record from the disk obtained image can be reproduced accurately. The stabilization of only the color subcarrier signal is sufficient, however not enough to compensate for the gross timing errors caused by warping or eccentricities of the plate be generated. In order to keep such time errors small, an arm extension transducer is used to control the scanning needle can be continuously adjusted along the groove of the image plate. Control signals for the arm extension converter can be derived from the phase difference signals generated by the detector 22. Phase difference signals are particularly suitable for controlling the arm extension transducer because they are relatively noisy or can be generated accurately and without interference. Of the approximately 2000 times during each disk rotation Recurring sync signals some are sufficient to form a phase difference signal, which the Can follow timing errors of the rotating optical disk exactly.

According to the drawing, an extension converter 34 is controlled by signals received from the phase detector 22

fts can be derived. The transducer 34 can be designed similar to a relatively small loudspeaker, as shown in FIG the above-mentioned US-PS 37 11 641 is described. The cone of the 1-speaker can for example

be mechanically coupled to the stylus, and that The speaker's electromagnetic field may be coupled to the source of the phase difference signals.

A frequency-compensating network (frequency compensator 17) receives signals from detector 22 and acts as a network with a lead-lag effect in order to keep the phase shift of the signal to converter 34 low. The signals phase-compensated by the network 17 are sent to the converter 34 via an amplifier 28. The amplifier 28 provides a relatively low source impedance for the signals controlling the transducer 34. By applying appropriate signals to the transducer coil, the stylus can be caused to translate along the spiral groove in the optical disc. The amplitudes of the signals fed to the transducer 34 and the crystal- controlled oscillator 40 are expediently set in the following manner: First, the gain factor of the amplifier 28 is set so that the tremors in the displayed image are compensated as far as possible. After the image shake has been reduced to a subjectively acceptable level, the gain of the signal for the crystal controlled oscillator 40 is adjusted. For this purpose, the gain of the signal fed to the crystal-controlled oscillator 40 is set by turning the gain controller 54 to such a high maximum value that the jitter stabilization of the reproduced image is not impaired. Too high a gain of the signal fed to the oscillator 40 reduces the amount of the correction signal for the converter 34. Too low a gain, on the other hand, can impair the stability of the chrominance signal and thus the chrominance in the displayed image. By properly adjusting the gains of the signals for both transducer 34 and crystal controlled oscillator 40, it can be achieved that the displayed image has subjectively acceptable colors and minimal tremors.

By controlling the arm extension converter using the phase difference signals used in the phase locked loop an otherwise necessary additional circuit effort can be dispensed with. Further this ensures that the converter receives relatively interference-free and very precise control signals will. A better control signal for the arm extensor is thus obtained by using the phase difference signal for this purpose uses which of the circuit for phase stabilization of the burst signals in the composite television signal picked up from the optical disc is generated.

The F i g. 2 shows as a block diagram an embodiment of the invention which contains a circuit arrangement for coupling a desired signal amount to the converter 34 and the crystal- controlled oscillator 40. Those parts of FIG. 2 which have the same function as corresponding parts of FIGS. 1 meet are denoted by the same reference numerals

The mode of operation of the arrangement according to FIG. 2 is similar to that according to FIG. 1 to the point where the output of phase detector 22 is coupled to oscillator 40 and transducer 34. The band filter 21 selects a sideband of the modulated color signal for application to the phase detector 22.

The signals generated by the phase detector 22 are passed via a buffer amplifier 28 to an active filter 30 and to a summing circuit 32. The filter 30 modifies the signals fed to it and then transmits them to the arm extension transducer 34 via a variable resistor 36. The transducer 34 is mechanically coupled to the scanning needle in the scanning arm 14 and causes this needle to move mechanically. A low-pass filter 38 also receives signals from the filter 30 and sends them to the summing circuit 32. The signals summed in the circuit 32 are sent to the voltage-controlled crystal oscillator 40, which in turn acts on the push-pull modulator 18.

In operation of the circuit described above, the output signals of the filter contain 20 color sync pulses, their oscillation frequency from 1.53 MHz in the baseband signal to 3.58 MHz and 6.64 MHz in the frequency-converted signal is misplaced. The band filter

21 receives output signals from filter 20 and passes components in the range of 3.58 MHz, so that the color sync pulses of the lower sideband of the converted television signal pass through this filter. The oscillation phase of the color synchronizing pulses appearing at the output of the filter 21 is recorded in the detector

22 compared with that of a 3.58 MHz reference signal, which comes from a relatively stable frequency source 24.

The resulting difference signal appearing at the output of the phase comparator 22 is via a Terminal 27 is given to the buffer amplifier 28, which has a relatively low impedance on the active Filter 30 and the summing circuit 32 are coupled.

The resulting difference signal from the output of the detector 22 is used to stabilize the entire television signal by means of the above-mentioned arm extensor and the color sync signal by means of a suitable feedback loop. Stabilization of the burst signal is desirable so that the color decoding in a television receiver takes place correctly. A stabilization of the entire television signal is desirable in order to keep undesirable effects in the reproduced picture as a result of the above-mentioned warping and eccentricities of the plate as low as possible. It is useful to provide both types of stabilization. The correction process in the stabilization of either the burst signal or the entire television signal consists in both cases of reducing the amplitude of the difference signals supplied by the detector 22. The gain setting of the differential signals is therefore of particular importance for each stabilization circuit. The difficulty of achieving a desired level of signal gain for each of the stabilization circuits is overcome by using filters 30 and 38.

The color subcarrier frequency is stabilized by shifting the frequency of the voltage-controlled crystal oscillator 40 in accordance with the difference signal supplied by the detector 22 as before.

The stabilization of the entire television signal is done by applying phase difference signals to the arm extension converter 34.

When the playback speed of the turntable in the player 10 is about 450 revolutions per minute then the speed changes in the received signal repeat about 7.5 times each Second. Because of the change in speed with each disk rotation, filters 30 and 38 become so set that at 7.5 Hz differential signals in the stronger Measure to the arm extension transducer 34 than to the voltage-controlled crystal oscillator 40. The

Filters 30 and 38 are discussed further below with reference to FIGS. 3 described in detail. By doing that for correction If the arm extensor is used at relatively low frequencies (e.g. 7.5 Hz), gross speed errors can occur must be kept to a minimum in the derived television information.

At the output of the filter 20, signals appear which have been stabilized both by the arm extension transducer 34 and by the voltage-controlled crystal oscillator 40. A transcoder (the details of which are described in U.S. Patent Application No. 5,066,446, filed September 16, 1974 under the name John Amery and entitled "Comb filtering for video processing") receives the stabilized signals from the filter 20 and converts these signals into a, ₅ format, which can be easily decoded with a normal television receiver 46.

According to FIG. 3, an input terminal of the buffer amplifier 28 is connected to the terminal 27 for receiving signals from the phase detector 22. The output signals of the amplifier 28 are applied to the non-inverting input of a further amplifier 52 via a resistor 80. _{A series circuit comprising a resistor 82 2J} and a capacitor 84 is also connected to the non-inverting input of the amplifier 52. The signals appearing at the output of the amplifier 52 are applied via resistors 90 and 92 to the inverting input of the amplifier and to the base electrodes of two transistors 58 and 60 forming a driver amplifier. The transistors 58 and 60 supply signals from their coupled emitters to the inverting input of the amplifier 52 via the series connection of a capacitor 62 and a resistor 64 and furthermore via a low-pass filter, which consists of the series connection of resistors 68, 70 and 72 with a bypass capacitor 74, to a summing connection 33. Two signal-limiting diodes 86 and 88 are connected in parallel with the capacitor 74. The summing connection also receives signals from the output of the amplifier 28 via two resistors 54 and 56 connected in series.

If no useful signal is picked up from the optical disc 12, then a noise barrier occurs (Squelch) in function, which is formed from a transistor 76 whose emitter is connected to the connection point of the two resistors 90 and 92 is connected. Control signals to operate this noise barrier are fed to the base of transistor 76 through resistor 78.

When the circuit shown in FIG. 3 is operated, the phase difference signals (error signals) generated by the phase detector 22 (FIGS. 1 and 2) are passed to the amplifier 28 via the connection 27. The amplifier 28 is adapted by feedback of an output terminal to its inverting input so that its gain is 1, the &> at the output of amplifier 28 signals provided are fed to the amplifier 52. This amplifier 52 provides an active filter, to the right signals for both the Provide arm extensors as well as the voltage controlled oscillator. The signals generated by buffer amplifier 28 are fed to terminal 33 via summing resistors 54 and 56 and also arrive at the non-inverting input of amplifier 52. The amplifier 52 contains RC toe members in order to obtain certain breakpoints in its frequency response curve. The first FLC time constants are formed by resistors 80 and 82 and by capacitor 84. This /? C time element leads to kinks in the frequency response of the amplifier at around 7.5 Hz and 59 Hz. A second /? C time element is formed by the resistor 64 and the capacitor 62. This second timing element leads to a kink at approximately 59 Hz. The two kink points formed at 59 Hz coincide with a kink in the frequency response of the transducer 34. A curve representing the frequency response or the transfer function from terminal 27 to the output of converter 34 is shown in FIG. 4a shown. The output variable of the transducer has the dimension of a speed and the input variable has the dimension of an electrical amplitude. The ordinate, calibrated in decibels, only shows relative values.

The transistors 58 and 60 are connected as emitter followers and cause a current amplification of the signals supplied by amplifier 52. The signals coming from transistors 58 and 60 will be given via the resistor 66 and the terminal 39 to the arm extension transducer. Since the electrical part of the Arm extension transducer has a relatively low impedance, it is appropriate to provide a control circuit that supplies a relatively low current to the arm extension transducer at frequencies close to 0 Hz. To one Achieving low converter current near zero frequency or DC frequency is the voltage controlled Crystal oscillator 40 arranged so that it exhibits a maximum amount in the vicinity of 0 Hz Receives differential signals. By having the signals applied to oscillator 40 at extremely low frequencies have the greatest gain, the signals provided by detector 22 will be is kept to a minimum, with the result that the control signal current supplied to the arm extension transducer 34 is at low frequencies is kept to a minimum.

The relatively low impedance signals provided by the emitters of transistors 58 and 60 are used also fed to a low-pass filter, which through the resistors 68, 70 and 72 and the capacitor 74 is formed. This low pass filter has a 3 db point at around 0.27 Hz, which is in common with the frequency response of the amplifier 52 leads to an overall frequency response as shown in FIG. 4b is shown. This curve shows the frequency response of the amplitude from terminal 27 to terminal 33 in the event that the latter with 180 ohms is complete and that the connection between resistors 54 and 56 is open The resistance value of 180 ohms represents the input impedance of the voltage controlled crystal oscillator 40. That open the connection between the resistors 54 and 56 prevents signal transmission from the output of the Amplifier 28 through these resistors to the summing connection 33, so that the frequency response of the The path running through the filter 30 and the low-pass filter 38 can be examined by the low-pass filter 38 Delivered signals arrive at the connection 33 and add up there with those signals that are directly from amplifier 28 to terminal 33. For the combined signal formed at terminal 33, a applies Frequency response as shown in Fig.4c. the

two diodes 86 and 88 contained in the low-pass filter prevent unintentional strong signal excursions, the could for example be caused by glitches.

If one compares the relative frequency response of the active filter and the converter 34 shown in FIG. 4a with the frequency response according to FIG. 4c compares which is decisive for the signal supplied to the voltage-controlled crystal oscillator 40 (connection 33), then one can arrive at a resulting curve as shown in FIG. 4d. This curve shows the relative gain difference between the frequency response of the arm extensor and the frequency response of the voltage controlled crystal oscillator. On the basis of Fig.4d can be seen that the compared the Armstreck-, ₅ transducer 34 associated frequency response of the amplitude with the relevant for the oscillator 40 frequency response is a maximum at about 7.5 Hz has. This gain maximum makes it possible for the arm extensor to effect a correction to the desired extent for speed errors which are caused by eccentricities and warpage of the image plate. It should be noted that the frequency range within which the arm extension transducer is most responsive to error signals is relatively narrow. _2J By this frequency range is kept narrow, the Armstreckwandler 34 performs an effective correction of speed errors without compromising caused by the voltage controlled crystal oscillator 40 correction phase errors of the color burst signal.

The noise barrier transistor 76 is connected to the amplifier 52. This transistor is located saturation during those periods in which a useful signal is derived from the optical disc. In the absence of such useful signals, e.g. B. if no record is currently being played, the base receives the Transistor 76 via resistor 78 a control signal which blocks this transistor. When locked Transistor 76 are output signals of amplifier 52 through resistors 90 and 92 on the inverting input of the amplifier coupled, whereby its gain factor to practically the Value 1 is changed.

The circuit arrangement described above shows that you have a relatively low-resistance arm extension transducer Can couple DC-wise with an associated control circuit without him high input currents suspend at extremely low frequencies. By correctly setting the time constants on the filter 38 and the active filter containing the amplifier 52, the strength of the output signal of the Increase converter at a frequency corresponding to the speed of the image plate, so that the arm extensor the speed errors caused by eccentricities and warping of the plate can effectively compensate.

In addition 5 sheets of drawings

Claims (13)

Patent claims: 1. Device in an optical disc player for correcting speed and phase errors in signals picked up from a rotating optical disc by means of a scanner an arm extension transducer coupled to the scanner and a reference signal source, thereby characterized in that with the scanner (14) a device (18,40) for frequency conversion of the coupled to signals obtained from the sampler; that the signals from the frequency converter (18,40) and Reference signals from the reference signal source (24) are fed to a phase comparator (22); that the phase comparator (22) via a control device (17, 28, 30, 36) for adjusting the position of the Scanner depending on the signals from the phase comparator with the arm extension transducer (34) is coupled; and that the phase comparator (22) also with the frequency converter (18, 40) a device (54) for controlling the conversion frequency is coupled. 2. Device according to claim 1, characterized in that the frequency converter (18, 40) has a Contains superimposed arrangement (18) and a filter circuit (20) which is connected to the phase comparator (22) is coupled, so that the arm extension transducer (34) signals that are substantially in a first Frequency range, and the superposition arrangement (18) signals essentially in one second frequency range Hegen, can be supplied. 3. Device according to claim 1 in an optical disc player for playing back optical discs with a Groove in which luminance, chrominance and color synchronizing information are recorded thereby characterized in that the device for frequency conversion is coupled to the scanner (14) Decoding device (16) for decoding the signals played back from the optical disc (12), a voltage-controlled oscillator (40) and a superposition arrangement (18) of the signals from the decoder and the voltage controlled oscillator are supplied to the decoded To convert signal in frequency, and that the reference signal source (24) is a reference oscillator, which delivers signals at substantially the same frequency as the color sync information in the has converted signal, and an error detector (22), which the signals from the superposition arrangement (18) and from the reference oscillator (24) to Generating an error signal are supplied, which via a coupling arrangement (54,30,32,38) is fed to the voltage controlled oscillator to control its oscillation frequency. 4. Device according to claim 3, characterized in that that the error detector (22) with the arm extension transducer (34) via a first filter circuit (30) is coupled to the converter relatively low-frequency control signals with relatively high To feed amplification, and that the signals from the first filter circuit (30) to the voltage controlled Oscillator (40) via a second filter circuit (38) are fed to the voltage-controlled To raise signals fed to the oscillator at extremely low frequencies. 5. Device according to claim 3 or 4, characterized in that the error detector (22) is a Phase comparator is whose output signal is proportional to the phase difference between the signal from the reference oscillator and a color synchronizing component in that from the superposition arrangement (18) delivered signal 6. Device according to claim 3, 4 or 5, characterized in that the frequency of the output signal of the reference oscillator (24) is essentially 3.58 MHz and that the color synchronizing component also has a frequency of essentially 3.58 MHz in the converted signal. 7. Device according to one of claims 3 to 6, characterized in that the superimposition arrangement (18) has a balanced input for receiving television signals and on its output supplies frequency-converted signals, which are essentially free of baseband television signals. 8. Device according to one of claims 3 to 5, characterized in that the voltage-controlled Oscillator (40) a voltage controlled crystal oscillator with an output frequency of about Is 5.11 MHz. 9. Device according to claim 4, characterized in that that the first filter circuit is an active filter with a frequency response that is a Has a kink at a frequency corresponding to the rotational frequency of the optical disc 10. Device according to claim 4 or 9, characterized characterized in that the second filter circuit (38) is a low-pass filter, the frequency response of which is a Has a kink at a frequency below 1 Hz. 11. Device according to one of claims 3 to 10, characterized in that between the superimposition arrangement (18) and the error detector (22) a band filter (21) is connected, which the color synchronizing components to the error detector lets through. 12. Device according to one of the preceding Claims, characterized in that the amplitude of the arm extension transducer (34) supplied Control signals at low frequencies is increased. 13. Device according to claim 12 for an optical disc player with a nominal optical disc speed of 450 rpm, characterized in that the amplitude of the control signals for the arm extension converter is raised at a frequency of about 7.5 Hz (Fig. 4d).