DE2900397C2 - Color television signal display device - Google Patents

Description

From DE-OS 26 46 806 is a circuit arrangement for recording and / or reproducing Known color television signals, which is designed so that when recording a color television signal in one track, the signal phase at each horizontal scanning period is advanced by 90 ° and in the adjacent track the signal phase at each horizontal scanning period is delayed by 90 °, whereas during playback the signal whose phase is a Has experienced lead, phase delayed in a corresponding manner by 90 ° and the signal whose Phase has been delayed, is advanced in a corresponding manner by 90 ° in the phase, and with the result that the original signal is obtained from the reproduced signal. With this known arrangement, it is possible to receive a color television signal without beat disturbance and without Record guard strips between adjacent tracks and with a relatively narrow frequency band and play back. Although azimuth heads are used in recording and playback, With regard to the frequency-converted carrier chrominance signals, there is no beat disturbance. The color television signal is one of the frequency

modulated luminance signal and the frequency band-converted carrier chrominance signal Signal.

In the case of a color television signal according to the PAL system, the V-axis component is known to experience the Carrier chrominance signals generally have an inversion symmetrical with respect to the U-axis, namely 1H for each horizontal scanning period is used to reduce beat interference and crosstalk components 26 46 806 known from DE-OS 26 46 806 between the adjacent tracks Measures on a PAL color television signal, the The V-axis component of the carrier chrominance signal is continuously aligned in one direction, and it an artificial MTSC signal is created. So they go with the PAL system achieved elimination of phase distortions and the improvement of color reproduction lost. These advantageous properties have been achieved by placing the component in the V-axis direction was switched every horizontal scanning period. This switching technique is the original Characteristic of a PAL system. In a PAL color television signal there is a correlation between every other horizontal scanning period, i.e. H. between every 2 Η period because the component of the V-axis direction of the carrier chrominance signal in every horizontal scanning period, d. H. is switched in every I Η period. Taking this correlation into account in every other horizontal scanning period or in every other horizontal scanning line was already in an older patent application published as DE-OS 28 56 634 describes a circuit arrangement, which is better suited to the needs of PAL color television signals

A circuit arrangement described in DE-OS 28 56 634 for recording a PAL color television signal contains a first separating circuit for separating a luminance signal from a PAL color television input signal, devices for frequency modulating the separated luminance signal and generating '■ ines frequency-modulated luminance signal, a second separating circuit for Separation of a carrier chrominance signal from the PAL color television input signal, a first signal processing device which freque izewise shifts the separated carrier chrominance signal in a band below the band of the frequency-modulated luminance signal and the phase of the carrier chrominance signal by 90 ° for each successive horizontal scanning period shifts the specific period, while a <"· following, specific period does not shift the phase, and means for assembling the frequency-modulated luminance signal and the carrier chrominance signal and for recording the resulting multiplex signal in a plurality of successive tracks which are offset parallel to one another on a recording medium, the recording being carried out in such a way that a carrier chrominance signal, the phase of which is successively shifted by 90 °, and a There are carrier chrominance signals whose phase is not shifted To reproduce the PAL * color television signal recorded in this way, a circuit arrangement is described in DE-OS 28 56 634, which is characterized by devices for picking up the signal recorded on the recording medium, a third separating circuit r: m separating the frequency-modulated luminance signal from the picked up signal, devices for demodulation deo separated frequency-modulated luminance signal, a fourth separating circuit for separating the signal-processed carrier chrominance signal from the picked up signal, a second Sig nalververarbeitungeinrichtung which converts the separated signal-processed carrier chrominance signal into the original frequency band and shifts the phase of the carrier chrominance signal by 90 ° at each successive horizontal scanning period during the specific period and does not phase shift during the subsequent specific period in order to restore the original carrier chrominance signal with its original Phase, i.e. without causing successive phase shifts of 90 °, a device for delaying the output signal of the second signal processing device by two horizontal scanning periods, a device for mixing the output signal of the second signal processing device and the output signal of the delay device and a device for mixing the demodulated luminance signal and the carrier chrominance signal appearing at the output of the first-mentioned mixing device in order to convert the PAL chrominance regain television signal.

In ^ he circuit arrangement according to DE-OS 28 56 634 signals are thus added to one another to avoid crosstalk interference, the are correlated with each other with respect to every other scan line. In particular, a signal that passes through a 2 Η delay line has been sent mixed with a signal that does not pass through the delay line has been delayed

However, the reproduced chrominance signal inevitably contains signal components relating to the luminance signal has been delayed by two horizontal scanning periods (2 H). In addition, that is The chrominance signal system of a PAL color television receiver is equipped with a 1 Η delay line. As a result, the reproduced chrominance signal becomes up to 3 H periods with respect to the luminance signal delayed This gives rise to difficulties, for example color image shading during reproduction of the image on the screen and, depending on the image displayed, there may be a decrease the picture quality come.

When crosstalk phenomena occur, a certain amount of color image shadowing can be seen by the Accept devices to avoid crosstalk, as crosstalk processes are more disruptive and the devices mentioned reduce the disruptive crosstalk to a remarkably high degree. However, if the video heads follow the recording tracks exactly and therefore only a little crosstalk or no crosstalk occurs at all, the opposite causes the luminance signal component delayed chrominance signal component produces a disturbing color image shadowing.

Based on a color television signal display device described in DE-OS 28 56 634 according to the preamble of claim 1, the invention is based on the object with little or In the absence of crosstalk, the devices that would otherwise eliminate the crosstalk are selectively shut down to prevent color shading.

This object is achieved by the measures in the characterizing part of claim 1. If now with the

The video heads reproduce the individual tracks accurately scan and accordingly little or no crosstalk occurs, the works Control device such that the gate circuit controls the signal path between the delay device and interrupts the mixing device. This avoids disturbing shadowing of the image.

Since the SECAM color television signal has chrominance signal components which are frequency-modulated signals, the above-mentioned means for eliminating crosstalk cannot be applied to a SECAM color television signal. However, there are reception areas in which either PAL or SECAM color television signals can be received. In these reception areas it can therefore happen that you want to record a SECAM color television signal and play it back later. Care must then be taken to ensure that the successive phase shift of 90 ^{: is} not carried out either during recording or during playback. In the circuit arrangement for reproducing the color television signal, it is therefore unnecessary to send the picked up or reproduced SECAM signal through the 2 H delay line. In a preferred development of the invention, therefore, when a SECAM color television signal is reproduced, the signal path with the 2 H delay line is interrupted, as is also the case when preventing the occurrence of color image shadowing.

Preferred embodiments of the invention are explained with reference to drawings. It shows

F i g. 1 is a block diagram of a recording arrangement used in connection with a first embodiment of a color television signal reproducing arrangement can be used according to the invention,

F i g. 2 shows a section of the track pattern on a recording medium with the recording arrangement according to FIG. 1 has been described,

F i g. 3 is a block diagram of the first exemplary embodiment of the color television signal display arrangement according to the invention;

FIGS. 4A and 4B are diagrams for explaining the Reasons why crosstalk can be avoided with the aid of the arrangement according to the invention,

F i g. 5 is a block diagram of the most important parts of a second embodiment of the invention Display,

F i g. 6 is a block diagram of a recording arrangement used in connection with a third embodiment of the color television signal reproducing arrangement can be used according to the invention,

F i g. 7 is a block diagram showing in detail a part of the block diagram according to FIG. 6 represents

8 shows a block diagram of the third exemplary embodiment of the arrangement according to the invention and

F i g. 9 is a block diagram of the most important parts of a fourth exemplary embodiment of one according to the invention Display arrangement.

First, on the basis of Fi g. 1 an example of a Recording arrangement explained for operation in connection with a first embodiment of FIG color television signal display device according to the invention is suitable

A PAL color television signal applied to an input terminal 10! (Color image signaling device according to the PAL system) is a low-pass filter 11 with an upper limit frequency of 3 MHz, a band-pass filter 15 with a pass band of 4.1 to 4.7 MHz and a horizontal synchronizing signal separating circuit 17 fed. A luminance signal passed by the low-pass filter 11 is converted into a frequency modulator 12

frequency modulated. The resulting frequency-modulated signal, which has a frequency deviation in a band of 3.8 to 4.8 MHz is a high-pass filter 13 with a lower cut-off frequency of 1.2 MHz. The high-pass filter 13 removes from the frequency mod-

the unwanted components. The output of the high-pass filter 13 arrives at a Mixing stage 14.

A carrier chrominance signal that has passed through the bandpass filter 15 is sent to a frequency converter 16

fed, which shifts it with the aid of a signal from a further frequency converter 20 into a frequency band which is lower than the band of the frequency-modulated luminance signal
A horizontal sync signal received from the

ΐ f cnniCMüiiüng

Frequency multiplier 18 in its frequency with a factor

multiplied, where m is an integer. The frequency-multiplied signal in this way is shifted in frequency in the frequency converter 2C with the aid of a signal from a reference oscillator 19. The resulting output signal is fed to the frequency converter 16

In the following, the frequency of the color subcarrier of the carrier chrominance signal, which is allowed through by the bandpass filter 15, is referred to as "/ c" (4.43361875 MHz). The frequency of the color subcarrier of the frequency-shifted carrier chrominance signal in the frequency converter 16 is called "/ s". The abbreviation for the horizontal sampling frequency is "/"". The frequency shift or frequency conversion is carried out in the frequency converter 16 in such a way that the frequency fs of the color subcarrier frequency converted in this way assumes a value which is given by the following equation:

(D

In the embodiment under consideration, m- 176. fs is therefore 692.308 kHz. The oscillation frequency of the reference oscillator 19 is equal to fo

The carrier chrominance signal appearing at the output of the frequency converter 16 is fed to a phase shifter 22 which is located in a phase shifter circuit 21. 1 shown as a circuit containing the phase shifter 22 and a switch 23. The phase shifter 22 operates so that it can shift the phase of the input signal fed to it by 0 °, 90 °, 180 ° and 270 °, respectively. The output signals resulting from the phase shift can be at fixed contact points a I, a. 2, a 3 and a 4 are accepted. In the switch 23, which is designed as a channel switch, the rotatable contact is successively switched to the next fixed contact point during each horizontal scanning period during a field or field period,

whereas in the subsequent field or partial image ^ period the rotatable contact remains connected to the fixed contact point a 1 Phase shifter circuit 21 from a signal during a certain field period, the phase of which for each successive horizontal scanning period each is advanced by 90 * In the following field period, however, a signal is derived, desstii phase is not postponed and consequently remains so, how she is

The horizontal synchronization signal is vötl der Isolating circuit 17 of a switch control circuit 31 fed. Furthermore, for each vertical scanning period, i. H. for each field or field period, by one Sensor 30 synchronized with the rotation of a rotary device device 28 derived a signal which is applied to the control circuit 31. The output of the control circuit 31 controls the movable contact of the switch 23 of the phase shift circuit 21.

The output signal of the phase shift circuit 2i passes to a low pass filter 24 which removes the unwanted components in the signal. The output signal of the low-pass filter is applied to the mixer 14 in which it is modulated with the frequency Luminance signal is multiplied. The resulting multiplexed signal is stored in a recording amplifier 25 amplified and then fed to rotating video heads 26a and 266 which alternate the record successive fields or partial images on a moving recording tape 27.

The video heads 26a and 266 are on the turntable 28 arranged at diametrically opposite points a motor 29 driven. The rotating video heads 26a and 266 have azimuth gaps shown in opposite directions are inclined at an angle of, for example, 6 ° with respect to the direction, which is perpendicular to the scanning direction of the heads, as shown in FIG. 2 indicated is also seen from FIG. 2 that one track 35a during one field period from head 26a and one track 356 is recorded by head 266 during the subsequent field or field period. The two Lanes 35a and 356 are in close contact with each other. The following lanes 35c; 35c /, ... are has been recorded by the heads 26a and 266 alternately.

For example, a signal for a field or partial image can be recorded by the head 26a, in which the movable contact of the switch 23 rotates in the direction of the arrow ^. The head 266 then records a signal for a field or partial image in which the movable contact of the switch 23 does not rotate. As a result, a signal appears in the track 35a, the phase of which is advanced by 90 ° for each successive horizontal scanning period, as shown in FIG. 2 is indicated by the designations Ao, Au A ₂ ,... A signal is recorded in the track 356, the phase of which is not shifted. This is shown in FIG. 2 indicated by the designations Bo, Bu Bz, ...

Next, a first is based on FIG Embodiment of the inventive arrangement for reproducing a signal explained in the has been recorded on the recording tape in the manner described above

In the reproducing device, the tracks recorded on the recording tape 27 are alternated scanned and reproduced by the rotating video heads 26a and 266, respectively. At the same time, the Video heads are controlled so that the head 26a tracks the tracks 35a, 35c,.,. and head 266 tracks 356, 35 </, ... scans. As is known, at the edge of the recording tape 27 for each revolution of the rotating device 28 a control pulse can be recorded, which is used to select the head.

The signals sampled by the video heads 26a and 266 are mixed and used in a playback amplifier 40 reinforced. The output of the playback amplifier 40 is a high pass filter 42 with a Lower limit frequency of 1.2MHz and one Low-pass filter 47 supplied with an upper limit frequency of 1.2 MHz The frequency-modulated luminance signal, which passes through the high-pass filter 42 is limited in a limiter 43 and then in a Demodulator 44 demodulated The luminance signal demodulated in this way then passes through a Low-pass filter 45, which is derived from the Signa! the ui'iciwüfiSCnicii Components removed, to a mixer stage 46.

The carrier chrominance signal which passes through the low-pass filter 47 is sent to a frequency converter 48 There is a voltage-controlled oscillator depending on a frequency signal 49 such a frequency shift or frequency conversion is carried out that the original frequency band is restored.

The color subcarrier frequency / s of the frequency-converted carrier chrominance signal which is fed to the frequency converter 48 undergoes a frequency conversion with the aid of a frequency Λ from the voltage-controlled oscillator 49. The color subcarrier frequency / j is converted into the original color subcarrier frequency fc by deriving the difference frequency (fa - fs) Formation of a difference frequency is carried out, a phase reversal of the carrier chrominance signal takes place in the frequency converter 48. The explained frequency conversion thus changes that of the tracks 35a, 35c; ... picked up signals recorded with phases advancing 90 ° in each successive horizontal scanning period into signals whose phases are successively lagging 90 °.

The carrier chrominance signal appearing at the output of the frequency converter 48 is fed to a phase shifter 51 in a phase shifter circuit 50. The phase shifter circuit 50 has the same structure as the phase shifter circuit 21 and, in addition to the phase shifter 51, which corresponds to the phase shifter 22, also contains a switch 52 corresponding to the switch 23 Channel switch designed switch 52 has a movable rotary contact, de « ^{1 is} controlled by the output signal of a switch control circuit 41, the operation of which depends on a signal that is detected by the circulation sensor 30. The control circuit 41 is also controlled by the output signal of a horizontal synchronizing signal separating circuit 53 which separates a horizontal synchronizing signal from the recovered color television signal at the output of the mixer 46

The phase shift circuit 21 of the recording arrangement and the phase shift circuit 50 of FIG Display devices can be replaced by a single phase shift circuit that performs the functions of the two circuits 21 uad 50 executes

The movable contact of the switch 52 of the display device shown in FIG. 3 rotates

in the direction of the arrow X drawn in for those signals which originate from the recording tracks 35a, 35c, ... and which, as a result of the frequency conversion, lag one another in phase by 90 °. The phases are now successively advanced by 90 ° in order to restore the original state. For the signals coming from the recording tracks 35Z>, 35d,. ■ originate and whose phases are not shifted, the movable contact of the switch 52 remains connected to the fixed contact point ιό a 1. In this case, there is no phase shift.

The phase of the carrier chrominance signal is thus turned back into its own by the phase shifter circuit 50 brought to normal condition. The signal appearing at the output of the phase shift circuit 50 is on the one hand to a gain switching stage 54 and on the other hand to a delay line 56 which delays by two horizontal scanning periods and is therefore called a 2 Η delay line will. The gain switching stage 54 delivers depending on the signal at a terminal 58 the input signal fed to it with an unchanged level to a mixer 55. That at the output of the 2 H delay line 56 occurring signal, which is delayed by two horizontal scanning periods, gets over a gate circuit 57, which is opened in response to the signal at terminal 58, also to the Mixing stage 55 and is mixed there with the non-delayed signal from gain switching stage 54.

In this connection, it should be noted that in the case of the PAL color television signal, the V-axis direction component of the carrier chrominance signal is switched for each horizontal scanning period 1H or vice versa will. For this reason there is no line correlation for directly successive horizontal scanning periods 1 H. On the other hand, for every second 1 Η period, i.e. H. for every 2 Η period, one Row correlation. Thus, if you have a signal that is through the 2 H delay line 56 by 2 H periods is delayed, mixes in the mixer 54 with a signal that is not delayed, two signals added together, the line correlation mentioned above exhibit. For this reason, the signal that is obtained as a result of the mixing process is complete free from harmful processes, and moreover, the crosstalk components cancel each other out and are thus removed. The following is explained.

The carrier chrominance signal thus occurring at the output of mixer 55 becomes, on the one hand, the mixer 46 supplied, in which it is mixed with the luminance signal, so that at an output terminal 62 the recovered color television signal occurs

It will now be assumed that, for example, at the time of reproducing track A of a signal which has been phase shifted in recording, track B of a signal which has not been phase shifted is simultaneously reproduced as a result of the passage by the frequency converter 48 and the phase shifter circuit 50 is brought the signal from the track a to its original state that a signal is produced which is not phase-shifted, since the reproduced from the track B signal, which has not been phase-shifted also by the frequency converter 48 and the phase shift circuit 50 arrives as a crosstalk component, it experiences a phase shift of 90 °. This crosstalk component signal Bc from track B is thus brought into the form of a Signsh which has been shifted by 90 ° for every 1 H period, ie for example in lines / 0, A, h, ... , as indicated by corresponding Arrows in FIG. 4A is shown from FIG. 4A, however, it can also be seen that the signals of every second 1 H period, that is to say, for example, the signals in lines h and h or the signals in lines / _t and h, have mutually opposite phases. Consequently, with regard to this crosstalk component signal Bc, the signals which have passed through the 2 H delay line 56 and which have not passed through this delay line are mixed with each other in the mixer 55 so that they cancel each other out. The crosstalk component signal Bc is consequently not present in the output signal of the mixer 55.

Similarly, it can be assumed that at the time of reproducing the signal of track B, the signal of track A is reproduced at the same time. While the B track signal is being reproduced, the phase shift circuit 50 does not phase shift. Therefore, at the output of the phase shift circuit 50, the signal obtained from the track B occurs without a phase shift. The crosstalk component signal Ac from track A also appears at the output of the phase shift circuit 50 without experiencing a phase shift therein. However, since the signal of the track A has already been phase-shifted during the recording, the phase of the crosstalk component signal Ac at the output of the phase shift circuit 50 changes continuously, as shown in FIG. 4B is indicated by arrows. With regard to the crosstalk component signal Ac , two signals are also mixed with one another in the mixer 55, one of which has experienced a corresponding delay in the 2 H delay line 56 and the other is not delayed Signal cancellation. The crosstalk component signal <4c is therefore not present in the output signal of the mixer 55.

As a result, the crosstalk component signal from the A track with respect to the J track and the crosstalk component signal from the Sin track with respect to the A track are effectively mutually canceled and thus suppressed

The carrier chrominance signal appearing at the output of mixer 55 becomes one of the other Color synchro-signal gate circuit 59 supplied The occurring at the output of the color-synchro-signal gate circuit 59 The color sync signal arrives at a phase comparator 60. The phase comparator 60 compares the Phase of the burst signal with the phase of a stable reference frequency signal whose frequency is the same the chrominance subcarrier frequency / c of the PAL color television signal and that is from a reference signal oscillator 61. The phase comparator 60 inputs corresponding phase error signal to the voltage-controlled oscillator 49 and thus controls it Vibration frequency. The loop from the color sync gate circuit 59, the phase comparator 60, the reference signal oscillator 61 and the voltage controlled Oscillator 49 forms a conventional automatic phase compensation or phase locked loop.

When during playback the video heads 26a and "26Ö scan the individual tracks exactly or the following individual tracks exactly, there is little or no crosstalk at all. In this

F? Ll v4rd the signal essentially not through the 2 H delay line 56 to avoid the problem of color image shadowing.

Namely, if the tracking process is accurate, a signal appears at the terminal 58 that the Gain switching stage 54 and the gate circuit 57 is supplied. The signal appearing at terminal 58 can either be brought about with the help of a manually operated switch or win that the extent of crosstalk is automatically detected and only when there is no crosstalk or very little low crosstalk, the signal is generated. This will be explained in detail later

When this signal occurs at terminal 58, the Otherwise open or conductive gate circuit 57 closed or blocked With gate circuit 57 closed the signal occurring at the output of the 2 H delay line 56 can no longer pass to the mixer 55 reach. Furthermore, the signal present at connection 58 causes the gain switching stage 54 doubles its gain factor switches The gain switching stage 54 now increases the level of the signal from the output of the Phase shifter circuit 50 by twice and carries the signal increased to twice the level of the Mixer 55 closed. Mixing stage 55 yeasts accordingly an output that has not been subjected to crosstalk cancellation processing, and which therefore does not contain a signal component that has been delayed by 2 Η periods. In view of the switched gain factor of the gain switch stage 54, the signal appearing at the output of mixer 55 has the same level as in Open or conductive gate circuit 57.

The reproduced carrier chrominance signal occurring at the output of the mixer 55, which is in the Mixer 46 is mixed with the reproduced luminance signal, therefore has no opposite Luminance signal has a delayed signal component. The recovered at output terminal 62 Accordingly, the color television signal does not cause any color shadowing in the reproduced picture.

On the other hand, however, the arrangement explained can also be designed in such a way that the gate circuit 57 is normally closed or blocked and only then opened or brought into the conductive state when a signal appears at terminal 58 which is generated as soon as the amount of crosstalk in the The reproduced signal exceeds a certain value. The gate circuit 57 now delivers the Output signal of the 2 H delay line 56 to the mixer 55 on. There is also the possibility that depending on the observation of the playback picture on which a particular increase of the playback picture on which a particular increase in crosstalk can be recognized, from which Operator a switch can be closed with the effect that the signal at the connection 58 appears to open the gate circuit 57, which has been closed until then. The control of the amplification switching stage 54 then takes place in a correspondingly adapted manner. The opening and closing of the Gate circuit 57 and the switching of the gain switching stage 54 are not based on the explained control measures depending on the existence or nonexistence of the signal at connection 58 is limited. The control can be modified and converted into Depending on other conditions, for example, the occurrence of a signal '.hit a high level and a low level signal at terminal 58. In addition, the gain switching stage 54 can be omitted.

Another modification is that the 2 H delay line 56 is formed so that it the function of the gate circuit 57 takes over. In this case, the 2 H delay line 56 operates in Depending on the signal on terminal 58 to selectively turn on or off.

Finally, you can also on the rotating device 28 at points in relation to the scanning direction in front of the Video heads 26a and 266 are located, attach heads to detect the tracking in addition to the two Scan the side edges of the tracks to be followed by the video heads 26a and 266.

In FIG. 5 is a block diagram of essential parts of a second embodiment of the invention shown The phase shift and frequency conversion are carried out simultaneously. Farther a frequency shifter circuit and frequency converter are common both for recording as Playback also used. The amount of crosstalk is automatically detected for opening and closing to control the gate circuit.

When recording, a carrier chrominance signal is used from an input PAL color television signal separated by means of a bandpass filter which is similar to the bandpass filter 15 according to FIG The separated carrier chrominance signal then occurs at an input terminal 70 and arrives from there a frequency converter 71. In the frequency converter 71, the carrier chrominance signal is converted into a frequency band shifts that is lower than the band of the frequency-modulated luminance signal This frequency shift or frequency conversion is carried out as a function of a signal that is sent by another Frequency converter 72 comes from the frequency-converted color subcarrier frequency / 5 of the carrier chrominance signal is described by the equation (1) already given. The output signal of the frequency converter 71 appears at an output terminal 73. As shown in FIG. 1 is shown, then this signal sent through the low-pass filter 24 and then with the frequency-modulated Luminanzsignt ': in the Mixer 14 mixed The output of mixer 14 is fed by heads 26a and 266 on the Volume 27 recorded as it is on the basis of F i g. 1 and 2 has been explained.

During recording, the movable contact of a changeover switch 74 is in contact with a fixed contact point R. The voltage-controlled oscillator 49 is consequently supplied with a constant voltage. The output-side oscillation frequency fc of the voltage-controlled oscillator 49 is consequently constant. This frequency fc is fed to the frequency converter 72

A horizontal sync signal from the FIG. 1 horizontal synchronizing signal separating circuit shown 17 reaches a counter 78 via a connection 75. A signal from the sensor 30 is transmitted via a terminal 76 is fed to a flip-flop 77. The flip-flop 77 applies a rotary synchronization signal to the counter 78! that switches between a high level and a low level every vertical period will. The counter 78 consequently counts from 0 to 3 with two bits in order, for example, to alternate an addition process (leading) and a stopping process of the

Horizontal sync signal for each vertical period to repeat. The counter 78 therefore takes 1H in one vertical period every horizontal scanning period an addition in single steps

(00- * 01 -► 10 -.- 11-- 00- * ...) and stops in the the following vertical period starts the counting process.

The horizontal synchronization signal at connection 75 is also fed to a phase comparator 79. There, the phase of this signal is compared with the phase of a signal from a countdown circuit 81. The resulting error signal at the output of the phase comparator 79 is used to control the output frequency of a voltage-controlled oscillator 80, the center frequency of which is 4 /, The output signal of the voltage-controlled oscillator 80 is fed to the countdown circuit 81, in which the frequency of this signal is reduced by V ^ s, for example, to match to achieve with the horizontal scanning frequency f ». The signal, reduced in frequency, is then applied to the phase comparator 79

In addition, the output frequency 176 / Ή of the voltage controlled oscillator 80 is simultaneously fed to a phase shifter 82. This output frequency is divided or counted down, and a phase shift takes place in order to generate four types of signals with the frequency / s, which are differ from each other in phase by 90 °. These four signals have phase differences of 0 °, 90 °, 180 ° and 270 ° and are fed to a gate circuit 83. The gate circuit 83 also receives the output signal of a decoder 84, which works as a function of the counter 78 to only one output line of the decoder 84 at a time activate. The gate circuit 83 then operates in such a way that it forwards the four output signals of the phase shifter 82 in succession at every 1 Η period during a field or sub-period, whereas it is not active during the subsequent field or sub-frame period. The output signal of the gate circuit 83 is applied to the frequency converter 72 in order to convert the signal from the voltage controlled oscillator 49 in frequency. The frequency converter 72 consequently generates as an output variable a predetermined frequency signal, the phase of which is successively shifted by 90 ° in every 1 Η period during a field or field period and the phase of which is not shifted during the subsequent field or field period. As already mentioned, the output signal of the frequency converter 72 is fed to the frequency converter 71.

The carrier chrominance signal with a color subcarrier frequency f is accordingly fed to the connection 70 and then converted in the frequency converter 71 into a color subcarrier frequency f _s . At the same time, the phase of the carrier chrominance signal is shifted successively at every 1 Η period during a field or field period and is not shifted during the subsequent field or field period. An output signal is therefore obtained which corresponds to the output signal of the phase shifter circuit 21 according to FIG. 1 corresponds.

During playback, the movable contact of the switch 74 is switched to a fixed contact point P. A carrier chfominanzsignal, which is separated from a reproduced signal by the low-pass filter 47 according to FIG Horizontal synchronizing signal separating circuit 53 fed to the counter 78 via the connection 75. The output signal of the sensor 30 is applied to the connection 76 as in the case of the recording

The output signal of the frequency converter 71 is on the one hand directly and on the other hand via the 2 H delay line 56 and the gate circuit 57 of the mixer 55. The recovered carrier chrominance signal comes from the output of the Mixer 55 to an output connection 85. From there it becomes the one shown in FIG. 1 mixer stage 46 shown fed and also applied to the synchro-signal gate circuit 59 The at the output of the The color sync signal that occurs is then passed to the phase comparator 60. The phase comparator 60 compares the phase of the burst signal with the phase of the reference frequency signal from the reference signal oscillator 61, and the resultant error signal is generated in a manner similar to that of The first exemplary embodiment is used to control the voltage-controlled oscillator 49. While at the time of reproduction, the output signal appearing at the output terminal 73 is not used

The flip-flop 77, the counter 78, the phase comparator 79, the voltage controlled oscillator 80, the countdown circuit 81, the phase shifter 82, the Gate circuit 83 and decoder 84 operate in the same manner as already described in connection with the Record was written.

In addition, the output signal of the frequency converter 71 reaches a subtracting circuit 86 in which this signal is subtracted together with the signal from the 2 H delay line 56 is subjected. The resulting output signal of the subtracting circuit 86 has a level which That corresponds to the amount of crosstalk component contained in the reproduced signal The output signal of the subtracting circuit 86 is fed to a curve shaper 87 in which it is a wave or Is subjected to curve shaping, and the curve-shaped signal is then sent as a control signal to Gate circuit 57.

The curve shaper 87 thus generates a control signal as a function of the crosstalk component. This control signal causes the gate circuit 57 to open, so that the output signal of the 2 H delay line 56 can reach the mixer 55 via the open or conductive gate circuit 57, if the crosstalk component exceeds a certain level. If, however, the crosstalk component lies below this particular level, the control signal causes the gate circuit 57 to be closed or remains blocked, so that the output signal of the 2 H delay line 56 is not passed on.

If the above arrangement is applied to a color television signal recording and reproducing apparatus is used, which is used for recording and reproducing SECAM color television signals it is not required. Cross-talk processes through the use of the phase shifting devices described above to avoid. Consequently, in this case it is necessary to stop the operation of the Phäsehvef * To prevent shifting devices and furthermore the output signal of the 2 H 'delay line 56 to be locked during dcf recording as well as during playback. Next, embodiments related to recording will be explained and / or for the reproduction of SECAM * color televisions *

serve as visual signals.

The F i g. 6 shows a block diagram of a recording arrangement; which belongs to a third embodiment of a display device, which on hand the F i g. 8 will be explained. In FIG. 6 are parts, the parts according to FIG. 1 correspond with the same Provided reference numbers. There is no individual description of these parts

The carrier chrominance signal which has passed through the bandpass filter 15 becomes a chrominance signal gate 110 supplied, in which, using the horizontal synchronizing signal at the output of the horizontal synchronizing signal isolating circuit 17, a burst or a signal is obtained by gate control, the time period of which is that of the The signal obtained by the gate control is a color system detection circuit 111 supplied in detail in FIG. 7 is shown

The F i g. 7 it can be seen that the signal from

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A connection 120 leads to a ceramic filter 121 whose mid-frequency is 4.5 MHz. The SECAM color television signal generally contains a frequency-modulated signal (FM signal), which is obtained by using a carrier wave of 4.4 MHz with a (R - y / signal component is frequency-modulated, and it contains a further frequency-modulated signal (FM signal), which is obtained by frequency-modulating a carrier wave of 4.2S MHz and a (B - V> signal component. These FM signals exist alternately at every 1st H period: The FM signal before 4, <t MHz passes through the filter 121 while maintaining its high level, whereas the other FM signal of 4.25 MHz is subject to an attenuation which is to a large extent dependent on the filter characteristic of the filter 121 depends.

When the signal supplied to the input terminal 10 is a SECAM color television signal, the FM signals of 4.4 MHz and 425 MHz alternately at every 1 H-period from the color sym: hronsignal gate circuit 110 for a period of time corresponding to the Color sync signal corresponds to the PAL color TV signal When this signal reaches the filter 121, a signal appears at the output of the filter. that in everyone 1 Η period alternately has a high and a low level. The resulting output signal of the Filters 121 are used in a half-wave rectifier and 7.8 kHz resonance amplifier circuit 122, in the the signal experiences a half-wave rectification, one Adjustment with an envelope frequency of 7.8 kHz is subjected and reinforced. The sinusoidal output signal appearing at the output of circuit 122 from 7.8 kH? is in a rectifier circuit 123 rectified, and the resulting DC component is placed on a scarf: level 124.

If the input signal is a SECAM color television signal. If the rectifier circuit 123 outputs a signal to the switching stage 124. whose level exceeds a certain level. The signal from switching stage 124 succeeded !; then about one Connection 125 to Schältersleuefsdiialiung 31, Die Switch control circuit provides a control signal to the phase shift circuit 21. The 'signal from the Switch control circuit 31 then causes the phase shift circuit 21 to record a SECAM'Fäfbfefnsehsignäls a PhäSefTVefsefilungsverarbeitung does not perform

On the other hand, if the input signal is a PAL color television signal, the output signal of the filter 121 is constant. The rectifier circuit 123 therefore delivers no output signal. The consequence of this is that the phase shift circuit 21 operates in the manner as it in connection with the embodiment according to FIG. ί was explained.

Next, with reference to FIG. 8 describes a display device which is used for playback of the signal recorded in the manner previously explained. Parts in FIG. 8 made with parts match according to Figure 3, are provided with the same reference numerals. A single description of this Parts are omitted

The burst signal or the signal whose period corresponds to that of the burst signal, is output from the burst gate circuit 59 to the phase comparator 60 and a color system detection circuit 130 supplied The color system detection circuit 130 has a structure similar to that of the color system detection circuit 111 corresponds to that shown in FIG. 6 and 7 explained became. The color system detection circuit 130 thus provides an output signal with a different level depending on whether the reproduced signal is a SECAM or PAL color television signal

When the SECAM color television signal occurs, the gate circuit 57 is controlled by the output signal of the Color system detection circuit 130 closed so that the output of the 2 H delay line 56 is not forwarded. Furthermore, from the output signal of the color system detection circuit 131 the gain of the gain switching stage 54 is switched and the switch control circuit 41 causes the phase shifting circuit 50 to operate so that a phase shifting operation does not occur Consequently, when the SECAM color television signal occurs, the display device also performs like the recording arrangement no phase shift by, and the output signal of the 2 H delay line is not used.

In FIG. 9 an embodiment is shown, which combines parts of FIG. 9 in itself a recording arrangement and a reproduction arrangement. the Divide according to FIG. 5 are given the same reference numerals. A detailed description of this Parts are omitted.

During recording, the movable contact of a switch 140 is connected to a fixed contact point R. The recording signal present at connection 70 is fed to frequency converter 71 directly and via switch 140 to a color synchronizing signal gate circuit 141. The color synchronizing signal gate circuit 141 is designed so that the color synchronizing signal or a signal whose time period corresponds to that of the color synchronizing signal occurs at its output. For this purpose, the horizontal synchronization signal is applied to the color synchronization signal gate circuit 1 ^ 1 via a connection 142. The resulting perturbed signal is supplied to a color system detection circuit 143 which has the same structure as the color system detection circuit 111 shown in FIGS. 6 and 7 shark. In the ¹ color system detection circuit, it is determined whether the input color television signal belongs to the PAL or SECAM system. The phase shifter 82 performs its phase shift when the PAL color television signal occurs.

operation and omits the phase shift when activated by the signal from the detection circuit 143 a SECAM color television signal is displayed.

During playback, the movable contact of the switch 140 is switched to a fixed center timing point P. The output signal of the mixer 55 is fed to the color synchronizing signal gate circuit 141 via the switch 140 The gated signal at the output of the gate circuit 141 then reaches the color system detection circuit 143 -

Via 82 carries out the phase shift when the reproduced color television signal is from the PAL system On the other hand, it suppresses the phase shift due to the signal from the detection circuit 143 when a SECAM color television signal is present When the SECAM color television signal is reproduced, the gate circuit 57 is also closed in order to prevent the output of the 2 H delay line 56 reaches mixer 55

In addition 6 sheets of drawings

Claims (5)

Patent claims: 1. Color television signal reproducing device having means for picking up one on one Record carrier recorded signal, with a first separating circuit for separating a frequency-modulated luminance signal from the picked up signal! with a device for Demodulation of the separated frequency-modulated luminance signal and with a second separator to circuit for separating a signal processing new carrier chrominance signal from the received one Signal, the signal recorded on the record carrier being a composite signal Signal consisting of a frequency-modulated luminance signal that consists of a PAL color television signal has been separated and frequency modulated, and a carrier chrominance signal acts out separated from the PAL color television signal and converted into a frequency band below of the band oes frequency-modulated luminance 40 g üegi, and which has further been signal-processed in such a way that the phase of the carrier chrominance signal is shifted by 90 ° in each successive horizontal scanning period during a specific period, whereas a phase shift has not occurred in a subsequent specific period, and the composite Signal is recorded on the recording medium in such a way that in adjacent tracks there are side by side a carrier chrominance signal shifted in phase by 90 ° and a carrier chrominance signal not shifted in phase, and signal processing devices (48 to 5-, 71 , 72, 75 to 84) for frequency conversion of the separated signal processing carrier chrominance signal into its original · * frequency band and for phase shifting the carrier chrominance signal by 90 ° in each successive horizontal scanning period during the specifis chen period and to prevent this phase shift during the subsequent specific period in order to restore the original carrier chrominance signal to its original phase, means (56) for delaying the output signal of the signal processing means by two horizontal scanning periods, means (55) for ^f η mixing the output signal of the signal processing devices and the An
output signal of the delay device and a device (46) for mixing the demodulated luminance signal and the carrier chrominance signal occurring at the output of the first-mentioned mixing device (55) in order to recover the color television signal, characterized by a gate circuit (57) for switching through or interrupting the signal path between the delay device (56) ) and the mixing device (55) and a device (58, 86, 37, 130, 143) for controlling the operation of the gate circuit. 2. Playback device according to claim 1, characterized in that a gain switching device (54) is provided which switches the gain factor for the output signal of the signal processing devices and the correspondingly amplified signal of the first mentioned 45 50 55 60 65 th mixing device (55), the gain switching device being controlled by the control device in such a way that the level of the signal supplied by the signal processing devices to the first-mentioned mixing device increases when the gate circuit sends the signal from the delay device (56) to the first-mentioned mixing device (55) ) forwards 3. Playback arrangement according to Claim I _1, characterized in that the control device has means (86, 87) which detect a crosstalk component in the picked-up signal, and that these means control the gate circuit with their output signal. 4. display device according to claim 3, characterized characterized in that the detection means are characterized by a circuit (86) for executing a subtraction between the output signal of the signal processing devices (71,72.75 to 84) and the output signal of the delay device (56) as well as through a circuit (87) for Applying a control signal to the gate circuit as a function of the output signal of the subtracting circuit. 5. display device according to claim 1, characterized in that the control device Means (130, 143) for determining whether the recorded or reproduced color television signal belongs to the PAL system or the SECAM system, and if a SECAM color television signal is determined to generate an output signal which the signal processing devices at the Prevents execution of the phase shift operation and causes the gate circuit to stop the signal supply to interrupt from the delay device to the first-mentioned mixing device, wherein the SECAM color television signal when recorded on the record carrier Phase shifting process has not been suspended