DE2753535A1 - Time error correction of video signal from video recorder - delaying signal in fixed and variable delay stages under control of signal from synchronisation pulse phase comparator - Google Patents

Abstract

Video signals from the recorder are delayed in a first delay stage by at least a whole line period. An additional delay is produced in a second delay stage (12), controlled by error signals. Non-delayed synchronisation pulses of the non-delayed video signal are separated from the signal and compared in a first phase comparator (21) with reference signal pulses. The error signal is applied to an element (23, 24) controlling the delay of the second delay stage (12).

Description

Description The invention relates to a method for timing error correction of video signals as well as a device for carrying out this method according to the preambles of claims 1 and 4, respectively.

Those from video signal memories, in particular from video recorders Video signals are subject to timing errors for a variety of reasons. at Video recorders can cause these time errors, for example, due to inadequacy @ n in the positioning of the scanning heads, due to unreporting problems in the drive system as well as belt stretching or shortening.

Basically, a distinction is made between two types of timing errors. at the first type is essentially a phase jump caused by the transition of the video heads from track to track. The second type of time error cs are those caused by speed differences between recording and reproduction arise and, for example, also to an event that has occurred in the meantime Change in tape length can be attributed.

Time errors are especially a hindrance when a mixture of Signals from different sources is required.

Certain time error correctors are already known, ie always work with complex circuits.

The purpose of the Erfirduno is to develop a method or a device to provide that or the compensation for the type of timing errors described above made possible by simple means.

In order to solve the problem, according to the invention, those marked with Features of claims 1 and 4 described measures provided.

Advantageous developments of the subjects of claims 1 or 4 result from claims 2 and 3 or 5 to 11.

The invention is illustrated below according to that shown in the drawing Block diagram, for example, explained.

The composite signal arriving at input 10 is initially used as a delay line 11 is supplied with a fixed or fixed adjustable delay time and then arrives via a second delay line that is controllable with regard to its delay time 12, the function of which will be explained below, to output 13.

A first pulse separation stage 14 is also connected to the one gong 10 tied together. In it the horizontal and vertical frequency synchronizing signals are weighed from the composite signal present at input 10. The vertical frequency sync signals stand at their one output 15 and the horizontal frequency sync signals irc other output 16 is available. The same thing happens with a FBAS reference signal, dos at a second input 17 of the device for Is available and in which it is, for example, a completely normal teletype signal act on the core, which can be received both over the radio and from another Signal source. Of course, you can also use a clock here incoming sync; ron pulses are entered. It is important, however, that the input Done in accordance with standards, so that the lines are overlapped.

In a second pulse separation stage 18, the sync pulses of the reference signal from the composite video signal present at input 17 of the device won. The vertical frequencies are available at an output 19 of the second pulse separation stage 18 Synchronous pulses and cm other output 20 the horizontal-frequency synchronous pulses at.

In addition, from the output 20 of the second pulse separation stage 18 pending horizontalfrequc.nten sync pulses as well as the om output 19 of these Level pending vertical frequency sync pulses with a known per se Circuit 29 a full image recognition (for example with a frequency of 25 Hz) are derived, the signals of which are then passed on to the servo device.

With the output signals V and H of the first pulse separating stage 14 a further full image recognition stage 32 is activated. This stage can also of the output signals H and V at the outputs of the third pulses step 25 can be controlled. With the output signals of the two full screen identification levels 29 and 32 start in a third phase comparator 30 in a manner known per se an error signal can be formed, which via a circuit 31 a position encoder pulse delay causes and thus a coarse phase correspondence of the reference signal to the reproduced one Brings about a signal.

The ones at the outputs 16 and 20 of the first and second pulse separation stage 14 or 18 pending horizontal-frequency synchronization pulses become two separate ones Inputs of a first phase comparator 21 are supplied, at the output 22 of which is a in its size from the time offset of the two horizontal-frequency synchronizing pulses dependent error signal is present, which either directly or Ur an amplifier 23, which can also be designed as a controllable amplifier, a VC oscillator 24 is fed, which then in turn the delay time of the already mentioned controllable delay line 12 influenced.

The measures outlined above ensure that the delay time the controllable delay line 12 depending on the time error of the Video signal is influenced compared to a reference signal and the error is thus corrected will.

The one that already exists with regard to a drop-out compensation Delay line 11 allows a fixed or fixed adjustable delay an advance regulation, so that the regulation is already fully effective, if that in the delay line 11, for example, by a full line period delayed video signal at the input of the controllable delay line 12 arrives.

A further improvement in the control mismatch can be achieved by that from the - delayed in the delay lines 11 and 12 - video output signal in a third pulse separation stage 25, the horizontal-frequency sync pulses again tapped and then in a second phase comparator 26 with the horizon frequency Syrchronim? Ulsen at the output 20 of the second pulse separation stage 18 are compared. The error signal present at the output 27 of the second phase comparator 26 becomes fed to a control input 28 of the controllable amplifier 23 and in this manner depending on the need for an amplification or weakening of the VC oscillator 24 supplied error signal reached.

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Claims (11)

METHOD FOR TIME ERROR CORRECTION OF VIDEO SIGNALS AND DEVICE FOR IMPLEMENTING THIS PROCESS Patent claims method for time error correction of video signals, preferably of video signals coming from image storage devices, wherein the video signals in a first delay stage by a fixed amount be delayed by at least one full line period, characterized in that, that in a second delay stage (12) a controllable by error signals additional delay is achieved that can be used for synchronization undelayed pulses of the undelayed video signal are separated from it and converted into a first phase comparison (21) with corresponding pulses of a reference signal be compared and that the resulting error signal is sent to an actuator (23, 24) is supplied, whereby the delay of the second delay stage (12) is correspondingly is yesterday. 2. The method according to claim 1, characterized in that the controlled Delay of the second delay stage (12) is readjusted in that for the synchronization usable impulses cus the already delayed Video output signal separated and with reference signals suitable for synchronization are compared and that the error signal thus obtained in addition to the control the second delay stage (12) is used. 3. The method according to claim 1 or 2, characterized in that by an additional phase comparison, known per se, between the actual and reference signals a full-screen synchronization and, if necessary, a PAL-correct synchronization takes place. 4. Apparatus for performing the method according to claim 1, characterized characterized in that in addition to a first delay line (11) with a fixed Delay a controllable second delay line (12) for the already pre-delayed Video signals are present, that a first phase comparator (21) is present, that of the instantaneous, usable for synchronization, from the video input signal separated pulses and corresponding pulses of a reference signal can be supplied and the resulting error signal can be tapped at its output (22), wherein the output (22) of the first phase comparator (21) with the input of a VC oscillator (24) is connected, the output of which in turn is connected to the control input the second delay line (12) whose delay can be controlled is. 5. Apparatus according to claim 4, characterized in that between the first phase comparator (21) and the VC oscillator (24) an amplifier (23) is arranged. 6. Apparatus according to claim 5, characterized in that it is is a controllable amplifier (23). 7. Device according to one of claims 4 to 6, characterized in that that to control the delay in the second delay stage (12) a clocked CCD memory (chorge-coupled device memory) is available. 8. Device according to one of claims 4 to 6, characterized in that that for controllable additional delay a bucket-chain circuit with controlled ßaktung is available. 9. Device according to one of claims 5 to 8, characterized in that that a first input of a second phase comparison stage (26) from the video output signal separated pulses that can be used for synchronization and the second input corresponding reference signals can be supplied to the second phase comparison stage and the output (27) of this second desk comparison stage (26) with the control input (28) of the encapsulated amplifier (23) is connected. 10. Device according to one of claims 4 to 9, characterized in that that a stage known per se for full-image recognition (29, 32) consists of a Pulse separation stage (13, 21, 26) obtained horizontal and vertical frequencies Impulses are supplied. 11. Device still one of claims 1 to 10, characterized by that one can be regulated by an output signal of a further phase comparison stage (30) Position encoder delay stage (31) is available. Description