DE3317645A1 - Recorder which records a sound carrier - Google Patents

Abstract

A video recorder in which the sound channel (7) is switched between the two video heads during the overlap time (t1-t4) in the scanning by two video heads (K1, K2). Phase equality between the two sound carriers (FM1, FM2) is achieved by a phase shifter (3) which is cyclically switched to various discrete values. <IMAGE>

Description

3317S45

TELEFUNKEN Fernseh und Rundfunk GmbH Goettinger Chaussee 76

3OOO Hanover 91

Hanover, August 28th, 1983 PTL-H Wp / vβ H 83/35

Recorder with recording of a sound carrier

In video recorders it is known (DE-OS 31 10 968), one or several sound carriers frequency-modulated with sound signals with the To record video heads together with the image carrier on helical tracks of a magnetic tape. By this type of sound recording a higher sound quality is achieved compared to the NF sound recording on a longitudinal track of the tape. The sound carrier has E.g. a frequency of 2 MHz and lies in the lower frequency range of the picture carrier frequency-modulated with the video signal.

Since the recording is made alternately with two video heads with an overlay time, it is necessary when reproducing the paths for the frequency-modulated image carrier and the sound carrier from field to field between the two video heads: to switch. This changeover interferes with the path of the image carrier not because during the vertical retrace time between two Fields are not displayed anyway. In the way of the sound carrier, however, such a periodic switching can occur Disturbances cause the audio signal to be a continuous signal is without interruptions.

It has already been proposed (P 31 25 879) 1 the sound carriers from the two video heads to separate FM modulators demodulate and switch the audio channel in the LF path. Switching between LF audio signals can be made possible in practice without sound interference during playback. For this solution, the sound carrier must therefore first be demodulated. In practice, there is often a desire without demodulation of the sound carrier to carry out a frequency conversion into the original frequency of e.g. 5i5 MHz. It would therefore be a new modulation of a sound carrier is necessary.

It is also known (DE-OS 31 10 968) when playing the To add sound carriers from the two video heads and to feed an FM demodulator. During the mentioned overlap period the sound carriers of both video heads are then effective. By cultural influences the video heads as well as elastic and non-elastic deformations of the tape, however, arise between the sound carriers of the two video heads statistically fluctuating phase shifts. It can therefore occur during the overlap period The two sound carriers will be erased and the signal will drop after FM demodulation Causes interference. In order to avoid this signal drop, the two sound carriers are included in this known circuit different amplitudes are added, so that compensation is no longer possible.

It is also known (DE-OS 31 l6 130), the combined sound carriers to lead through a selective amplifier and to increase its gain during the head change so that the Amplifier oscillates at its resonance frequency. This is ensures that there is always a sound carrier during the head change is present, even if this is not modulated for a short time.

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It has also been suggested (earlier application P '52 '* 2 ^ 57), the phase relationship between the sound carriers fed to the inputs of the switch during the overlap time by a To control the manipulated variable so that the two sound carriers have approximately the same phase at the time of the switchover.

The invention is based on the object of providing a particularly simple circuit that can be implemented using digital technology To create this phase equality that does not cause any frequency corruption in the evaluated sound carrier and a phase adjustment over a full 360 without assistance an additional pilot carrier of lower frequency made possible.

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

The sound carrier of the beginning track on which during the overlap time is to be switched, is therefore independent of its respective phase cyclically one after the other during the Overlap time provided with different phase rotations. With a monitoring circuit it is constantly the phase relationship between the respective evaluated sound carrier of the ending track and the sound carrier checked the switchover is to take place. If the phase rotator makes the sound carrier with different phase positions sufficiently small Distance and a sufficiently large number is available, at some point there will be a sufficient phase correspondence between the two sound carriers. As soon as this is established, the audio channel is switched between the two video heads triggered.

The circuit according to the invention creates a phase adjustment range created by 36O. Advantageously occurs!, A Frequency change of the output signal so that the audio signal is not corrupted. It is also not required for that Establishing the phase match an analog control voltage

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to generate, so that necessary for such a control voltage Low passes are avoided. The phase rotators do not have to go into a defined starting position between the head changes to be postponed. The circuit can in particular can be set up as a digital circuit and can therefore be easily integrated.

The invention is explained using the drawing using an exemplary embodiment. Show in it

1 shows a block diagram of the circuit according to the invention, FIG. 2 curves for explaining the mode of operation of the circuit according to FIG. 1,

3 shows a practically tested embodiment of the circuit according to Fig. 1 in digital technology and

Fig. ^ T curves to explain the operation of the circuit according to Fig. 3-

Fig. 1 shows a video magnetic tape 1, from whose helical tracks the signals are alternately scanned with two video heads K1 and K2. On the magnetic tape 1, among other things, a frequency-modulated sound carrier is recorded, which is to be evaluated by the circuit. The evaluation of other recorded signals such as frequency modulated color carriers and the like is not dealt with in more detail for simplification. The sound carrier FM1 arrives from the first video head Kl via the selective, limiting amplifier 2a and the phase rotator which can be switched to eight different values ^ 1-Q? 8 3a on the switch k. The sound carrier FM2 from the video head K2 reaches the other input of the switch k via the selective, limiting amplifier 2b and the phase rotator Jb . The stages 2a and 2b -as well as 3 ^{a and} d 3 *> are identical.

The mode of operation of this circuit is explained in connection with FIG. The logic 5 is controlled by the 25 Hz pulse 6, which comes from the servo circuit of the recorder. The logic 5 supplies the phase rotator 3a with a constant manipulated variable Us which fixes the phase rotation of the phase rotator 3a at one of its values. The sound carrier FMl ¹ differs

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therefore differs from the sound carrier FM1 only by a constant phase rotation, which is not essential for further consideration. The sound carrier FML 'passes nuf the Plinsnnvnrgleichsstufe Ph. At the time ti is the switch ¹ I, so that at the terminal 7 or the phonogram FML is still in the position shown ^1. During the overlap period tl- tk , the pulse 6 appears with its negative edge and prepares the changeover of the switch k , but without triggering it. The pulse 6 essentially defines the direction in which the upcoming switchover has to take place. Starting from time t2 passes from the logic 5, the switching voltage 8 to the control input of the phase rotator 3b and effected cyclically changing the phase rotation in increments of ^{1 to} 15, a total of over 3 0 * of the period T of the sound carrier FM2. The sound carrier FM2 'switched in phase in this way also reaches the phase comparison stage Ph. Due to the constant phase of the sound carrier FMl ¹ and the phase of the sound carrier FM2 ¹ , which changes in stages, during the overlap period tl-t ^ t in the phase comparison stage Ph one sufficient de phase correspondence of FMl ¹ and FM2 'determined. At this point in time t3, the phase comparison stage Ph controls the logic 5. This then generates the switching pulse 9 according to Fig. 2d, the k switching of the switch to the dotted line position triggers, so that now the sound carrier FM2 'reaches the terminal 7. Since the phase equality between FM1 ¹ and FM2 ¹ is largely the same at this point in time, there is no disruptive phase jump in the sound carrier FM ¹ at terminal 7 during the switchover at time t3.

At the next switchover from FM2 ¹ to FM1 ¹ during the following overlap period t5-t6, the function of the phase rotators 3a and 3t> is interchanged. Then the phase rotator 3b is controlled with the constant manipulated variable Us and the phase rotator 3a with the switching voltage 8.

In Fig. 3 is indicated by the reference numerals from Fig. 1, which parts in Figures 1 and 3 correspond to one another. the

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Operation is explained together with FIG. 4, namely also for switching from the video head Kl to the video head K2. The letters a-f show at which points 3 shows the voltages according to FIG.

In the circuit according to FIG. 3, the phase rotators J> a and 3b each contain a delay element with four taps. The phase shift between successive taps is approx. 45. The signal from one of the taps is fed via a selection circuit to an EX-OR gate 10a or 10b, which acts as an inverter that can be switched on and off. With the aid of the three output signals of a 3-bit counter Zl or Z2, the selection circuits and the gates 10a and 10b are controlled so that eight different phase rotations are generated with one counting cycle of the counter, each differing by approximately 45. Depending on how the meter is connected, the phase settings can run in an increasing, decreasing or non-monotonic sequence. The number of taps in the runtime chain. can also be increased and the counting cycle increased accordingly. The transit times between the taps must always be selected so that the adjustable phase rotations are distributed approximately evenly over the range of 360.

At the beginning of the overlap time tl-t4, the phase rotator 3 ^{a is} still in the position which. was set for the previous signal switchover. The phase rotator remains in this position at least until the next switchover. The rotator 3bkann be in any position, the phase between the signals FML ¹ and FM2 'is dependent on mechanical variations of the track length and Kopfraddurchmessers opposite to the recording and the settings of the phase rotator. The phase comparison stage Ph consists of the EX-OR gate 11. If the phases of the two signals FM1 'and FM2 ¹ almost match, the gate 11 emits no or only very narrow positive pulses (Ph in FIG. 4) via the RC element 12 to the input of the monoflop I3. The RC element 12 causes this input of the monoflop 13

then remains at "O" so that the monoflop 13 is not triggered
can be.

As long as the positive pulses Ph exceed a certain width, the monoflop 13 is triggered in any case at an interval of approximately one period T of the signal FM. The circuit must be structured in such a way that this is guaranteed. That Monoflop 13 gives each time a pulse b (Fig. 4) of approx. 75% the period T from. This pulse switches the phase setting counter Zl or Z2 for the signal of the new track each one step further. At the same time another counter is used Z3 set to "0".

With sufficient phase matching by FML ¹ and FM2 'b.am the pulses output from the monostable multivibrator remain. 13 The phase shift then remains unchanged. The counter Z3 counts the periods of the FM signal. With a given value of periods, for example k or 8, the output of the counter Z3 goes to "1". Through this
the actual signal switching is initiated with switch k and it is ensured that all settings remain unchanged until the next head change. The counter Z3 prevents signal switching with switch 4 from being triggered by a signal interference. There is namely the possibility that the disturbance simulates a brief phase match at the inputs of the phase comparison stage Ph, which triggers the changeover of the switch k.

The time constant of the RC element 12 and the final value of the counter Z3 are matched to one another in such a way that the actuation of the switch k after phase alignment of FM1 ¹ and FM2 ^{1 is} sufficiently reliable within the overlap time tl-t'l
or t5-t6 takes place. In addition, means can be provided which, shortly before the end of the overlap time, bring about a forced changeover of the changeover switch k when the changeover is effected by the
Phase comparison stage Ph was not triggered. The switchover must then take place in any case, because at the end of the overlap time tl-t ^ i the signal would fail without switchover.

.. H some details of the circuit 3 will be discussed with reference to FIGS:

The level transitions of the pulses 6 synchronized with the rotation of the head should be in the first half of the overlap time t1-t4. Each level transition of this pulse sequence generates a start pulse according to FIG. K , which sets the counter Z3 to "0" (voltage a in FIG. K) . The pulses 6 also ensure that the flip-flop FF2 switches with the correct phase (voltage f), and that only the phase setting counter Zl or Z2 can be switched on, which adjusts the signal of the new track to the signal of the previous track must (voltage el or c2). As long as the voltage a in Fig. K is at "0", the phase is

P sen adjustment active. During this time, the monoflop 13 can be triggered, the counter Z3 receives counting pulses d, and the flip-flop FFl is reset so that the voltage e is "1". The starting position for the phase adjustment counter Z2 is "Ί" in the example of Fig. 3. In this position, the signal FM2 is only inverted via the EX-OR gate 10. When counting further, the phase of FM2 'is then rotated by ^ 5 per step. When the counter is set to "I ¹¹ , the most favorable phase setting is finally reached. In this position, phase fluctuations can result in a pulse at the output of the monoflop 13 before the counter Z3 has reached its final reading. In this case, a new phase adjustment cycle must be run through.

After the voltage a has gone to "1", the monoflop 13 can no longer be triggered, and the counter Z3 must maintain its position until the next start pulse. The flip-flop FFl is switched over with the next pulse d. The resulting falling edge of the voltage e causes the actual signal switching with the switch 4 via the flip-flop FF2 the phase synchronization is activated again. This could lead to significant disruptions. The OR gate lk has the effect that the changeover with the changeover switch k does not take place until

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if r * ■ '.!' ■ -: · '-. · Rrui et ρ τι Um-

switch no k «mn .- ;; . ■ - ', - ·.:. * ■ ·: ■ ^; · ■ · ■. ni! ? u; _: C does not interfere with the witches 1 ::: t ϊ ru i - ν <·:;: τ: M'-r n - '··; ::: r: cnstiTi Koni wpcliscl, so the rising edge of the pulses 6 , liuift the synchronizing and Umschnlt process in a corresponding manner.

The frequency of the switching pulses 8 (voltage c2 in Fig. ^) Is roughly equal to the FM carrier frequency. At one frequency of the sound carrier of 2 MHz, almost 2000 phase settings can be checked or checked during an overlap time of 1 ms. a setting cycle of 8 or 16 different phase rotations can be run through approx. 100 or 50 times. Delays in the Switching pulses 8 occur, however, when the phases match is already good and monoflop 13 is not triggered immediately at the beginning of the counting time of the counter.

The relatively large overlap time is definitely sufficient to - even in the event of malfunctions - to find a favorable time for the switch with a high degree of certainty.

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Claims (8)

Claims \ Ji Recorder with recording of a sound carrier (KM), which is scanned with an overlap time (tl-t'i) alternately with several heads (Kl, K2) from a magnetic tape (l), with a switch (^) that controls the sound channel (7) switches from a first head (Kl) to a second head (K2) during the overlap time, characterized in that during the overlap time (tl-t'l) the sound carrier (FM2) from the second head (K2) via a cyclic phase rotator (3b) switched to different discrete values (1-8) and fed together with the sound carrier (FMl) from the first head (Kl) to a phase comparison stage (Ph), the output voltage of which, with sufficient phase equality of the supplied sound carrier, enables the phase rotator ( 3b) stops and actuation of the switch (k) is triggered. 2. Recorder according to claim 1, characterized in that the values of the phase rotator (3) extend over a range of approximately 36Ο of the sound carrier period (T). 3. Recorder according to claim 1, characterized in that the different values (1-8) of the phase rotator (3) have a distance of approximately Ί5 ⁰ for the sound carrier period (T). k. Recorder according to Claim 1 or 2, characterized in that the phase rotator (3) contains a delay element with η taps which are connected cyclically one after the other to the input of an inverter (10) which is cyclically switched on and off, so that this inverter (10) outputs the sound carrier ( FM) delivers successively with 2n different phase positions. 5. Recorder according to claim 1, characterized in that the phase comparison stage (Ph) is formed by an EX-OR gate (ll). 3317845 H 83/35 6. Recorder according to claim 1, characterized in that delay means (Z3, FFi) are provided which cause the switch (k) to be actuated only when it is ensured that the phase correspondence has not been simulated by a brief disturbance . 7. Recorder according to claim 6, characterized in that the phase adjustment cycle can be run through several times before actuation of the switch (k). 8. Recorder according to claim 1, characterized in that shortly before the end of the overlap time (tl-t4) a forced release of the switch (k) takes place when the phase comparison stage (Ph) has not triggered a switch.