DE3233389A1 - Circuit for reducing head-change interferences in a recorder - Google Patents

Abstract

In the case of a recorder having alternating scanning by a plurality of heads, head-change interferences occur in the scanned signal. Therefore, the signal of a time interval in which a head change takes place is substituted by the signal of a time interval preceding it in time. In particular in the case of a video recorder, the signal of a line (48) having head-change interference is substituted by the complete signal of a line (47) or a plurality of complete lines preceding it in time. <IMAGE>

Description

Circuit to reduce head change disturbances

in a recorder There are video recorders known where with two on the circumference of a head drum rotating video heads the fields each on one The helical track of a magnetic tape can be recorded. So there is a change of head each at the end of a field. When displaying images, they are caused by the head change disturbances, but these are with a properly adjusted television set not visible in the picture because they are just before the V-pulse.

There are also video recorders known (DE-OS 30 18 037), in which the Video tracks are written as semicircular tracks approximately perpendicular to the direction of the tape will. These tracks are much shorter than the helical tracks in the case mentioned Helical tracking. A complete Field are recorded, but only a fraction of a field, e.g. a package of 48 lines, where then about 13 such packages result in a complete picture with 625 lines. The scanning is carried out with several rotating video heads such that successive in the longitudinal direction of the tape Tracks are read one after the other by different video heads. This has the consequence that several head changes occur during a full picture and into a visible one Line can fall. A signal failure can be avoided by having a certain temporal overlap is provided in the scanning of the successive heads and the signals are superimposed. Such an overlay can lead to Phase jumps in the scanned frequency-modulated image carrier and thus likewise lead to disturbances in image reproduction. A head change in the course of the The signal used to reproduce the image is practically without any visible interference playback is not possible.

The described head change disorders can also be recorded in others Signals occur, e.g. when a PCM audio signal is received with a recorder according to DE-OS 30 18 037 recorded; -recorded. Then there can also be a disturbance of the sampled., Signal over multiple words or groups of words occur.

The invention is based on the problem of disturbances in the scanned Avoid signal by changing the head during playback as far as possible.

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

There are so-called dropout compensation circuits for a video recorder known in which a dropout in the frequency-modulated with the video signal Carry the disturbed signal automatically by a temporally preceding signal is replaced. There, however, such a dropout occurs in a special circuit each determined and a switching pulse # to insert the substitute signal triggered. This circuit does not generally work for a certain period of time Elimination of head change disturbances, but only if a dropout is detected will. This known circuit and the circuit according to the invention are therefore simultaneous can be used to solve various tasks in one recorder.

The invention enables complete compensation of the through the head change caused disturbances in the signal, because the signal for the entire period, in which the head change disturbance can lie, through an undisturbed signal from one previous period is replaced, e.g. the video signal of a line with head change interference by the video signal of a temporally preceding line in which no head change The effect is also independent of the number of head changes during one Unit of time, e.g. during a frame of a television signal, since the insertion ! of the substitute signal takes place again with each head change. When at a video signal the head change disorder is spread over two or more consecutive ones Can extend lines, the insertion of the substitute signal extends as well over two or more lines. For example, the lines n + 2 and n + 3 are then scrolled through replaces lines n and n + 1. A substitute for the signal of one line in a video signal by the signal of the temporally preceding line as is well known possible without noticeable visible disturbance in the picture because the signals of two consecutive lines not at all or only slightly in practice undersceiden.

There are also television signals for which the coding or the type of modulation is changed from line to line, e.g.

for a PAL or SECAM color television signal. For the PAL color television signal is the phase of the burst signal and the modulated color subcarrier of the line switched to line.

Even if the image content is identical, they are only repeated in each second line identical signals. It is therefore advisable for such a signal to to replace the signal of an n line / by the signal of line n-2.

An embodiment of the invention is based on the drawing on Example of a video recorder explained. 1 shows the principle of operation of the invention, Fig, 2 in principle the insertion of the substitute signal, Fig. 3, a practical one Exemplary embodiment for the block diagram according to FIG. 1 and FIG. 4 'is a further development part of the circuit of FIG. 3.

In Fig. 1, the video recorder 1 works with a recording DE-OS 30 18 037, so that a disturbed signal FBAS 'is at terminal 2, the When a full image is running, there is a disturbance due to the head change in certain lines in the video recorder 1. This signal reaches the terminal via circuit 3 4, where there is a composite signal that has been freed from interference. In the circuit 3 is each during the lines in which disturbances from the change of head develop, the signal of one or more complete lines by a substitute signal from the or replaced the previous lines. The circuit 5 is used in addition to Field recognition, i.e. to differentiate between odd and even numbers Fields. This circuit delivers over the line 6 each at the beginning of a complete Image, so an odd-numbered field, a signal to the circuit 3. This is necessary to ensure correct counting of lines and Ensure triggering of the switchover to the substitute signal.

This is explained in more detail with reference to FIG. 3.

The replacement signal is inserted in the circuit 3 in each case for lines of certain ordinal numbers in a full screen where the head change takes place. The insertion is therefore only correct in terms of time if synchronism exists between the head changes and the image sync pulses, i.e. always the same Head scans the image sync pulse from the tape. If this synchronism does not exist, the replacement signal can be inserted in lines in which there is no head change takes place. Therefore, in the circuit 7, the synchronism between the from Band scanned image synchronization pulses and the head change pulses determined. if the synchronism is not present, the insertion of the Substitute signal in circuit 3 blocked. Only when the synchronism in the circuit 7 is recognized, the circuit 3 is effectively controlled.

In Fig. 2 it is assumed that during line 48 of a frame Disturbance 9 occurs due to a head change in the video signal, which occurs during image reproduction would become visible. By counting the lines of a full image, the row 48 determined. A key pulse T is generated during this line. This impulse T suppresses the disturbed signal of line 48 and instead samples the signal of the previous one Line 47 as a substitute signal during line 48.

The disturbance 9 is thereby completely suppressed. If by statistical Fluctuations the disturbance 9 can extend over the lines 48 - 49, so will with a key pulse T of double length during lines 48 and 49 the signal of the Lines 46 and 47 inserted as a substitute signal.

Fig. 3 shows a logic circuit with which the insertion of the substitute signal according to Fig. 1.2 is possible. The circuit is mentioned below for the three Functions dor circuits 3, 5, 7 according to FIG. 1 described.

Insertion of the substitute signal The disturbed signal FBAS 'is used by the Terminal 2 routed to terminal 4 via video amplifier 10. It also gets over the switchable delay stage 11 with the delay time of a line duration from terminal 2 to terminal i. Stage 11 is designed as a CCD delay stage and is controlled by the clock generator 12. The stage 11 can also be a conventional one Be delay line. In the synchronous separation stage 13, the line sync pulses Z is separated from the signal and fed to the phase comparison stage 14. The oscillator 15 oscillates at a frequency on the order of 1 MHz, which is an integer Is a multiple n of the line frequency. The frequency is included in the frequency divider divided down by the division factor n to the line frequency. The gained Voltage is also fed to the phase comparison stage 14. The output voltage the phase comparison stage 14 regulates via the delay stage 17 the frequency and phase of the oscillator 15 to that of the line sync pulses Z. This PLL circuit generates line-frequency pulses that are stabilized by the flywheel H generated by the action of the phase locked circuit 14-17 of interference in the line sync pulses Z are independent. The delay stage 17 holds the Control voltage from the output of the phase comparison stage 14 to the oscillator 15 also at Disturbances in the line sync pulses Z upright. It can also be used as a sieve member be designed with a correspondingly high time constant. The line-frequency pulses H are fed to the counter 18.

From the beginning of a frame, according to FIG. 2, this counts 48 lines and controls counter 19 at the beginning of line 48. The counter 19 generates starting with the line 48 for the duration of a line the key pulse T. This switches over the inverter 20 as an inverted pulse T 'the video amplifier 10 off and at the same time the delay stage 11 on. This is what is on terminal 2, with the Fault 9 affected signal blocked and instead from the output of the delay stage 11, the undisturbed signal of line 47 is switched to terminal 4. Whenever the counter 18 # the counter reading 48 according to FIG. 2 for triggering the counter 19 and Generation of the key pulse T has reached? it is reset via line 33 and then begins again with the counting process up to line 48 according to FIG Synchronous pulse separation stage 21 is a vertical blanking pulse V obtained, which the Switch S1 opens. This may cause interference from the image sync pulse avoided in the phase comparison stage 14.

Field detection During the duration of the vertical blanking pulse V the switch Sj is closed by the pulse V, so that the frame sync pulse reaches AND gate 22 from terminal 2. The head change impulse K of a certain Head goes directly to the AND gate 23 and through the delay stage 24 in time delayed on the multivibrator 25. This generates a pulse of a defined duration, which also reaches the AND gate 23. At the AND gate 22 is a time window formed that a certain portion of the frame sync pulse to the counter 26 feeds. The counter 26 counts the edges of the supplied signal. It is well known the impulse build-up of the vertical synchronous mix at the transition between the rear Compensation pulses and the line sync pulses in even and odd numbers Fields different, i.e. the number of pulse edges during one lying there Time window is different. The counter 26 gives e.g. 8 counted pulse edges as detection of an odd-numbered field from a pulse. This comes over the OR gate 27 to the switch S2, opens this switch and suppresses it an H: -; Pulse.;' This is necessary because of the odd number of 625 lines Full image so that the counter 18 can stay with its counting rhythm. There only now 624 lines are counted, the counting process according to FIG. 2 takes place during one frame thirteen times. This counting process is repeated - that is, identically from frame to frame Frame, so that the described insertion of the replacement signal with the pulse T of Frame to frame takes place in the same lines.

After a certain period of time, the counter 26 is over the aging stage 28 is reset so that the counting process can start again at the next field. In the next even field, the counter 26 counts seven pulse edges and does not provide a pulse at its output, so that in younger Way with the switch S2 no H-pulse is suppressed. The combination of the impulse K and the pulse from generator 25 in OR gate 23 is not essential required because the pulse from generator 25 alone represents the time window. the AND stage 23 is only used for further self-interference suppression, since it generates pulses outside of the: pulse K does not pass. A circuit to differentiate the Odd-numbered and even-numbered fields is also described in DE-PS 15 97 473.

Synchronism between head change and frame sync pulse As on Hand of Fig. 1 explained, it must be ensured that the insertion of the Brsatzsignals-with the pulse T occurs only when the Viäeo heads have the correct, i.e. assigned to them Scanning tracks, i.e. a certain head always only the signal belonging to it and only the same video head scans the vertical sync signal from the tape. To this The purpose is the V-pulse via the delay stage 29 of the phase comparison stage 30 supplied. The stage 30 also receives the head change pulse K via the switch 54 supplied.

The delay time of stage 29 is such that when correct Scanning of the tracks by the video heads the pulses V and K at the inputs of the Level 30 are simultaneous. The switch S4 is closed by the V pulse. As a result, the head change pulse K can only go to the step during the duration of the V pulse 30 arrive. If the scanning is correct, the head change pulse K appears during the Duration of the V-pulse. The duration of the V-pulse is so long that despite the delay in stage 29, the pulses V and K at the inputs of phase comparison stage 30 are simultaneous with correct scanning. The switch S4 ensures that The head change pulse K reaches stage 30 only if the scanning is correct.

If there is synchronism, the circuit 30-32 acts on the counter 18 and gate 27 does not enter. If there is no synchronism between the pulses K and V exists, the stage 30 generates at the output of the holding circuit 31 a signal that the Schmitt trigger 32 controls. This changes the output voltage of the Schmitt trigger 32 so that the counter 18 is reset. In addition, the gate 27 is the switch S2 open for the duration of a field. Then no more H-pulses can be applied the counter so that the counting of these pulses and the insertion of the substitute signal are blocked with the key pulse T in the desired manner. In this case it doesn't Correct scanning of the tracks by the video heads would result in the insertion of the substitute signal not in the correct lines with head change disorders. Once synchronism is reached, controls the output voltage of the stage 30 via the holding circuit 31 the Schmitt trigger 32 in its other position. The Schmitt trigger 32 has now no more influence on the counter 18 and the switch 32. Now the described can Counting from the beginning of an image in the described; Way.

FIG. 4 shows a further development of the PLL circuit 14-17 in FIG. 3. The hold circuit is located between the output of 14 and the control input of generator 15 (Sample and Hold) 34, which is also controlled by the Z line sync pulse. During the phase comparison between the line sync pulse Z and that from the generator 15 coming pulse in the phase comparison stage 14 is on line 35 a generated by the phase relationship dependent control voltage. This control voltage is by the hold circuit 34 during the remainder of the period between the pulses, ie. throughout the line trace, so that a constant control voltage UR arises on line 36 during this period. The pulses Z supplied via line 7 to stage 34 control the hold circuit 34 so that the control voltage UR only changes when a pulse arrives Z can change to a new value. The control voltage UR is therefore in each case during the duration of a line is constant, but can vary depending on the beginning of each line change abruptly from the result of the phase comparison in stage 14. These Compared to the circuit with a filter element, the circuit has a high time constant Advantage that the control voltage UR the result of the phase comparison in the Level 14 adapts without inertia, but remains constant during a line. When a Line syrichron pulse Z fails due to a disturbance, occurs in the synchronization also no possible malfunction, because then the control voltage UR is due to the missing Impulse on line 37 cannot change and in a desirable way on the original Value remains.

Claims (14)

Claims S circuit for reducing head change disturbances in a sampled signal from a recorder, in particular a video recorder, in which the scanning is carried out periodically alternately by different heads, thereby characterized that in each case during the period (line 48) in which a head change takes place, the signal of this period of time by the signal of a temporally preceding, period of the same length (line 47) is replaced. 2. A circuit according to claim 1, characterized in that at one Video signal in the line (48) in which the head change takes place, the signal of the entire line (48) is replaced by the signal of a temporally preceding line (47) will. 3. A circuit according to claim 2, characterized in that the signal replacement takes place in several consecutive lines. I 4. A circuit according to claim 2, characterized in that I the entire FBAS or BAS or S signal of a line by the corresponding signal a chronologically preceding line is replaced. 5. A circuit according to claim 1, characterized in that the signal replacement takes place in the path of a sampled carrier frequency-modulated with the signal. 6. A circuit according to claim 1, characterized in that at one Bisequential color television signal (PAL, SECAM) the signal of a line with the temporal Ordinal number n is replaced by the signal of the line with the ordinal number n-2. 7. A circuit according to claim 1, characterized in that the signal in parallel via a delay stage (il) that can be switched on and off and via a signal amplifier (io) that can be switched on and off and for the insertion of the Substitute signal, the delay stage (11) is switched on and the amplifier (10) is switched off is. 8. A circuit according to claim 2, characterized in that from the Zeilensynchronirnpul sen (Z) separated from the video signal via a PLL circuit a sequence of flywheel-stabilized line-frequency pulses (H) obtained and a Counter (18) is fed, each after a fixed number of lines triggers a pulse (T) to insert the substitute signal. . 9. A circuit according to claim 8, characterized in that in the way of Control voltage of the PLL circuit is a key and hold circuit (34) which the respectively! the control voltage obtained during the phase comparison is maintained and only through the line sync pulse can be controlled to a different value of its output voltage is. 10. A circuit according to claim 3, characterized in that the path the line sync pulses (Z) to the PLL circuit (14-17) during the duration of the Frame sync pulse is interrupted (switch S1). 11. A circuit according to claim 8, characterized in that a circuit (22 - 25) to distinguish between odd and even fields Evaluation of the different structure of the vertical synchronous mix provided is, which emits a pulse at the beginning of a frame, which in the dem Counter (i8) supplied pulse sequence one pulse: suppressed. 12. A circuit according to claim 2, characterized in that the signal replacement is blocked if there is no synchronism between the head change pulse (K) of a head and the vertical sync pulses of the sampled signal. 13. Circuit according to Ahspruch 2 and 7, characterized in that the Delay stage (11) a CCD delay stage for the duration of one or more Lines is. 14. Circuit to differentiate between odd and even numbers Fields of a television signal, characterized in that the sync pulse train of the signal ;. and a pulse that occurs only during the vertical blanking period the inputs of an AND gate (22) are applied and that to the output of the AND gate (22) a counter (26) is connected, which is only counted when a certain number of Pulse edges emits an output pulse.