DE2920912A1 - AZIMUTH CORRECTION OF HEAD COLUMNS - Google Patents

Description

December 20, 1978 1 PHN 9136 C

Azimuth correction of head gaps.

The invention relates to

a method by which a gap of a reproducing head with respect to a magnetic recording medium attached signal, brought into the correct angular position or held in this position, in which the Phase difference between two 'sampled signals of the same shape measured and a control signal for the Correcting the angular position of said gap is derived.

Such a method is known from US Pat. No. 2,751. ^ 39, after which a multiple ¥ playback head simultaneously scans a number of related parallel tracks, of which the outer tracks contain identical signals. The initial values of those Parts of the multiple magnetic head it that these outer tracks sample, are each fed to an input of a phase comparison circuit, depending on the amplification, from which the signal at the output, which is a measure of the phase difference between said output signals of the magnetic head, one Device is supplied which corrects the error in the angular position of the playback head. The purpose of this is Time error in the video information recorded in the associated parallel tracks caused by an incorrect Angular position of the gap are brought about to correct.

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December 20, 1978. 2f jv PHN 9136 C

A wrong position of the gap

however, it also results in poorer reproduction of the high frequencies. For example, a deviation of only a playback head a few g-vad minutes for one Audio signal reproducing the high frequencies by some decrease kHz, like this. that it will be clear that for this reason too it is desirable to always be in the right position of the gap.

In the known method, however, at least one additional track is required to the To be able to adjust the head correctly, which is at the expense of the amount of information to be recorded. It is also e.g. possible with multi-track recording and playback devices, that the tracks are not all recorded on the same device, so the correct location varies from track to track and so cannot be preserved for all traces.

The invention has the task

to provide a simple and useful method that corrects the position of the head gap for each track possible without the need for additional tracks.

For this purpose, according to the feature of

Invention, the sampled signals are obtained by simultaneously displaying the upper and lower halves of a Information track are scanned separately.

When determining the phase difference

can distinguish between the two sampled signals difficulties arise because of the irregularity of the same. These are according to a further embodiment of the process according to the invention thereby avoided that the time difference between two related zero crossings of the sampled signals is measured will..

According to another embodiment of the method according to the invention, the the sampled signals are each sent through a low-pass filter, whose cutoff frequency is below half the

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Frequency that belongs to a signal whose period is equal to the maximum distance between two related zero crossings.

This clearly determines which zero crossings of the sampled signals belong together because it is desirable that the minimum distance between two zero crossings of the same Signal at least twice larger than the maximum distance between two related zero crossings of both signals is. The minimum distance between two Zero crossings of the same signal is determined by the cutoff frequency of the filter.

According to yet another embodiment of the method according to the invention, the the sampled signals are each sent through a bandpass filter, whose bandwidth is preferably equal to two octaves and whose highest cutoff frequency is lower than half of the frequency that belongs to a signal whose period is equal to the maximum distance between two related signals Is zero, and that is for Audio applications preferably from + 2 to + 8 kHz extends.

This ensures that the

Control speed is not too low, while the harmonics of the separated low frequencies are still are still available for the regulation.

When the signals filtered in this way are fed directly to a phase comparison circuit would be, it would be possible that in the absence of a signal or in the case of small signals, the zero crossings of the Noise can be used for regulation; however, these zero crossings are not exactly the same because the two Noise signals are not correlated.

In order to take advantage of this possibility

^ ⁵ close, in yet another embodiment of the method according to the invention, depending on the filtering, the scanned signals are on the one hand via a first pulse shaper

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a time slot circuit and on the other hand via a Threshold circuit with a threshold equal to or greater fed as the noise voltage of the signal to a second pulse shaper, after which it is determined whether the The leading edge of this pulse falls within the time window, and if so, one at the end of the time window generated pulse is passed by a gate circuit, the sums of the durations of the time window and the generated pulse are chosen to be the same for both sampled signals, whereafter the generated pulses Both channels are each fed to an input of a phase detector the phase difference between the Measures the back flankeii of the generated impulses.

After another Ausig

implementation of the method according to the invention for For each stereo signal, stereo signals become the signals via an associated own control device of a logical one Circuit supplied in which the control signals are combined at the outputs of the phase detectors.

A device for carrying out the method according to the invention, which has a playback head en is provided whose outputs to the inputs of a phase detector for measuring the phase difference between the two signals sampled by the playback heads

lead the same shape, its output with a control device is connected to which an electromechanical transducer is connected, which determines the angular position of the playback head can set is characterized in that

the playback head belonging to each track consisting of two identical 30s

Divide for simultaneous scanning of the upper half and the lower half of an information track to be reproduced consists.

According to a further embodiment of the device according to the invention, each part is 35

of the playback head it is connected to a low-pass filter, whose cutoff frequency is lower than half the frequency that belongs to a signal, its wavelength

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the same, the gross tab stood between two corresponding ones Points of the column of the two parts in the playback head is measured in the direction of movement of the record carrier.

This clearly determines which zero crossings of the sampled signals belong together.

After further training the

according to the invention is each part of the playback head connected to a bandpass filter, the bandwidth of which is preferably equal to two octaves and the The highest cut-off frequency is lower than half the frequency that belongs to a signal whose wavelength is the same your main tab stood between two corresponding points is the column of the two parts of the playback head, measured in the direction of movement of the record carrier, which frequency band is for audio applications from + 2 to extends to + 8 kHz.

This ensures that the

Control speed does not get too low, while the harmonics of the low frequencies remain for that Scheme are available.

According to yet another embodiment of the device according to the invention, each part of the playback head via its associated filter on the one hand via a first pulse shaper with a time window circuit and on the other hand via a threshold circuit with a threshold equal to or greater than the noise voltage of the signal is connected to a second pulse shaper, the output of which is connected to a first input of a first AND ^ Circuit leads, "from which a second input to the Output of the time window circuit is connected, the also leads to the input of a delay line, its output on the one hand with a first input of a second AND circuit and on the other hand with the reset input a switching device is connected, whose set input is connected to the output of the first AND circuit is, the output of the switching device with

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the second input of the second AND circuit is connected, the output of which is connected to an input of the phase detector leads, while the sum of the durations of the time window of the time window circuit and the delay time of Delay line for both channels is almost the same.

After one more

Embodiment of the device according to the invention exist the associated time slot circuits and delay lines each of one and the same delaying controlled by a common RF clock generator Element.

This allows the differences between the sums of the durations of the time window of the Time window switching and the delay time of the delay

rungs1eitung.for both channels by choosing the frequency of the Hp_i> _a j _c tgenerators made as small as desired, because the maximum error is equal to the duration of a whole pulse interval of the clock pulses.

After another execution

form of the device according to the invention consists of the phase detector of two logic circuits with two inputs each, the output of which is on the trailing edge of one Signal at the first input is set when the other

Input has a first logic level, and back-25

is set or held in the reset state when the other input has a second logic level, the first input having the first logic circuit connected to the second input of the second logic circuit and the first input of the second logic circuit 30th

is connected to the second input of the first logic circuit.

This ensures that a signal only occurs at the output of the phase detector if

at the two outputs simultaneously a signal from the 35

two halves of the track occurs, the width of these output pulses proportional to the time shift between the zero crossings of the signals from the two track halves

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and therefore a measure of the error in the angular position of the Playback head is.

According to another execution

shape of the device according to the invention is for each stereo track its own control device available, the outputs of the two phase detectors of these control devices can be combined via a logic circuit.

lamit is achieved that in the event

of unequal angular errors of the two columns of the to the Stereo tracks. Heads set to the mean angle error and / or in the absence of a signal in one the two tracks can be regulated to the existing signal.

A magnetic playback head

according to the invention is characterized in that he Contains two adjacent magnetic cores, each with a playback gap vind an electrical winding are provided, the display columns being aligned with one another and each having a width that is at most equal

half the width of the information track to be read out.

For use in e.g. a

Stereo tape recorder, with the original mono track with a width of 1.5 mm already in two tracks each with a width of 0.6 mm with a gap of 0.3 mm

is split, it means that a magnetic head is required that has two magnetic cores, each one half of the scan one track, and contains two magnetic cores that each scan one half of the other track. This means that the head must contain four nuclei, each having a trace of

Coat a maximum of 0.3 mm. A head that fulfills this requirement cannot simply be built up, all the more so and space has to be found in which the four associated electrical windings have to be accommodated.

According to one embodiment of the

Magnetic head according to the invention - is now a storeo head, which itself generates a signal that is a measure of its azimuth position, characterized in that the magnetic head

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per track contains a short and a long magnetic core, the electrical winding of the long core, seen in the direction perpendicular to the running surface of the head, lies under the electrical winding of the short core.

'The assembly is further facilitated by the fact that it has been found that the lower and the upper half of the same track brush for a satisfactory effect of the magnetic head to the magnetic separation between the cores · need to be made no high requirements of ( which, however, is probably the case for the channel separation), which makes it possible to set the relevant cores against each other without a magnetic shielding plate, where they may only be replaced by, for example

a thin layer of glue, varnish or plastic from each other

are separated.

Some embodiments of the

Invention are shown in the drawing and are described in more detail below. Show it:

Fig. 1. the configuration of the head

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and tape,

Fig. Z shows the relationship between the

highest cut-off frequency of the filter and the angle error Of the head,

Fig. 3 shows an embodiment of a

25th

Circuit for measuring the zero crossings,

Fig. H shows another embodiment of this circuit,

5 shows that relating to FIGS. K and 6

appropriate truth table,

30th

Fig. 6 shows an embodiment with

a shift register as a delay element,

7 shows an embodiment of a phase detector,

Fig. 8 schematically and in plan-35

sees a magnetic head according to the invention with a Magnetic tape cooperates, and

9 is a view of a section

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through the head of Fig. 8 along the line H-II.

In Fig. 1 is a record carrier 1, which in this case is provided with two tracks and 3 in which a signal is recorded.

These tracks are scanned by a playback head 4 consisting of two parts 5 and 6, which parts are each provided with a playback gap 7 and 8, which are separated from one another by a small gap 9 and are aligned with one another. It is of course also possible to mount the two parts directly against one another without a gap 9. It is also possible to use other types of reproducing heads such as a magnetoresistive head. Each part here consists of a magnetic circuit which is provided with a winding, the gap 7 scanning the upper hold of the track 2 and the gap 8 scanning the lower half.

Fig. 2 shows the playback head

h according to FIG. 1 in a position which corresponds to the maximum deviation Oi from the correct position. Half the wavelength Λ of a recorded signal going to

Control of the angular position is used, must be greater than the distance a between two corresponding points b and c of column 7 and 8 of the two parts 5 and 6 of the playback head h , because otherwise the system no longer knows that the time at which the Zero crossing e has arrived at b must be compared with the time at which this zero crossing has arrived at c, and that only the time at which this zero crossing e has arrived at c does not have to be compared with the time at which the Zero crossing d has arrived at b.

In Fig. 3, the signal becomes a

Bandpass filter BF or BF ¹ supplied, whose bandwidth is preferably equal to two octaves and whose highest cutoff frequency is lower than half the frequency that belongs to a signal whose wavelength is equal to that

Maximum spacing a in FIG. 2 between two corresponding ones Points b and c of column 7 and 8 of the two parts 5 and 6, respectively, of the playback head 4, in the direction of movement of the

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Recording medium 1 measured, which frequency band extends here from 2 to 8 kHz. This bandpass filter BF or BF ¹ is on the one hand via a first pulse shaper PS ₁ or PS 'with a side window circuit TW or TW and on the other hand via a Sclrwel lens circuit TD or TD ¹ with a threshold equal to or greater than the maximum noise voltage a second pulse shaper PS _p or PS 'he connected? _s whose output leads to a first input 1 of a first AND circuit G ₁ or G ', of which a second input 2 is connected to the output of the time gate circuit TW or TW', which output also to the input of a delay line DL or . DL 'leads whose output on the one hand with a first input 1 of a two-tone AND circuit G_ or G' and on the other hand with your reset

input r of a switching device FF or FF 'is connected, the set input s is connected to the output of the first AND circuit G ₁ or G', the output of the switching device FF or FF 'with the second input 2 of the second AND -Circuit G 'or G' is connected, the output of which <t <t

leads to an input of the phase detector PD. The output of the plias detector PD is connected to a control device CD to which an electromechanical transducer T is connected, which can adjust the angular position of the playback head h. Such an electromechanical converter

25th

is known per se from US Pat. No. 2,751,239.

For reproduction purposes, the

The output signals of the two headers are added together, see above that then, a playback signal with a normal noise-signal ratio is available again.

The effect of this circuit

is as follows: The signal h taken out of the reproducing head is v _om bandpass filter BF and BF ¹ filtered and then has, for example under a in the truth table of Fig. 5

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specified shape. This signal is converted by the pulse shaper PS ₁ or PS · into a pulse, the leading edge of which coincides with the zero crossing of the signal a in FIG. This pulse indicated under b in FIG. 5 is fed to the time window circuit TW or TW, in which a pulse c according to FIG. 5 with a certain duration t _{1 is} generated. This pulse opens the first AND circuit G or G 'for signals at its first input 1.

The signal from the band pass filter

BF or BF ¹ is also fed to a threshold circuit TD or TD ¹ with a threshold indicated by k and 1 in FIG. 5, which is equal to or greater than the noise voltage, this circuit having the signal at its output

the second pulse shaper PS "or PS" forwards. the The leading edge of this signal always occurs later than the leading edge of the signal at the output of the bandpass filter BF or BF 'and is in the second pulse shaper PS or

PS 'converted into the pulse denoted by e in FIG.

This pulse is passed from the opened first AND circuit G or G 'to the set input s of the switching device FF or FF ¹ , which switching device thereby emits the signal denoted by f in FIG. 5 and thus the second AND- Circuit G_ or G 'for

a signal at its first input 1 opens. The trailing edge of the pulse c occurring at the output of the time window circuit TW or TW 'is passed on by the delay line DL or DL' as a positive level to its output, which level after a delay time t _p

returns to 0 again, so that the pulse d of FIG. 5 occurs at the outputs of the delay line DL or DL '. This ex "pulse is passed through the opened second AND circuit G or G 'and the input of the

Phase detector PD supplied. The trailing edge of the Impul-35

ses d is also fed to the reset input r of the switching device FF or FF 'and sets this switching device back so that the second AND circuit G resp.

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G ¹ is closed again ". Since the sums of the durations of the time window t ₁ or t 'of the time window circuit TW or TW and the delay time t" or t' of the delay line DL or DL are chosen to be the same, the trailing edges of the Pulses g at the outputs of the second AND circuits G and G 'determine the time difference between the two related zero crossings of the sampled signals, ie the signals belonging to columns 5 and 6, respectively.

^ tor PD converted into a signal of which, depending on the type of phase detector, the amplitude or the pulse width is proportional to the time difference mentioned. This signal is fed to the control device CD, which in turn ^{controls an electromechanical transducer 1} T which is connected to the playback head h in such a way that it can set the angular position of the same and correct it as a function of the signal fed to it. A device according to NL patent application 78.05802 is preferably used for the control device CD.

20th

The mentioned pulse shapers PS ₁

or PS * and PS or PS 'can be used in different ways be formed. For example, an amplifier stage with a very large gain can be selected for this purpose, which is connected to a limiter circuit that

plitude limited to a certain value.

For the threshold circuit can

For example, a so-called Schmitt flip-flop ST or ST ¹ can be used, the flip-flop level having a value which is equal to the desired threshold voltage, whereby

30th

the threshold device TD or TD 'and the second pulse r former PS or PS' are designed combined. The first AND circuit G ₁ or G 'can also be combined with the switching device FF or FF' to form a D flip-flop,

whose D input the second input 2 of the first AND-scarf-35

tion G ^ or G «forms and its clock input as the first The input of the first AND circuit G or G 'is used. One another possibility is to use an amplifier with a large

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Reinforcement and built-in threshold to apply, the output of the amplifier being at one logic level if the signal from the filter BF or BF ¹ remains below the threshold value, and at the other logic level if this signal exceeds the threshold value.

As a time slot circuit TW or

TW, a monostable multivibrator MV or MV 'can be selected; this also applies to the delay line DL or DL ¹ . This is illustrated in FIG. K.

In Fig. 6, for which the

5 applies, it is indicated how the associated time window circuits TW or TW ¹ and delay lines DL or DL ¹ in a delaying

' Element can be combined, for which a shift register SR or SR' is used here, which is controlled by a common clock generator CG · which emits pulses with a very high frequency of, for example, 1 MHz.

The filter BF or BF 'is connected via the pulse shaper PS or PS' to the set input ck of a bistable flip-flop FF ₁ or FF ', the Q output of which is connected to the input of a shift register SR or SR ¹ and to the first input 1 of a third AND circuit G or G 'leads. The Q output of this bistable flip-flop FF ₁ or FF 'leads to the D input of a D flip-flop FF_ or FF' acting as a switching device, whose clock input ck is connected to the output of a Schmitt flip-flop ST or ST ¹ , which acts simultaneously as a threshold device and as a pulse shaper and in turn

is connected again to the band filter BF or BF '.

The output of the shift register SR or SR 'leads to the reset _{input r of the bistable flip-flop FF 1} or FF', to the second input 2 of the third AND circuit G or G * and via an inverter I to a first

Input 1 of the second gate circuit G or G ', whose second input 2 is connected to the Q output, the D flip-flops FF "or FF". The leading edge of the input

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impulses a from the filter BF or BF 'sets over the pulse shaper PS or PS' to the bistable flip-flop FF or FF ', whereby its output Q is low and this low level with the frequency of the clock generator CG through the shift register SR or . SR 'is pushed. At the same time, the output Q of the bistable flip-flop FF ₁ or FF 'is high, whereby the D flip-flop FF or FF »flips over when a pulse from the Schmitt flip-flop ST or ST' arrives, causing its Q output to go high and thus even

^ the second input 2 of the second AND circuit G or G ' gets high. When the low level at the output of the shift register SR or SR 'arrives, becomes the reset input r of the bistable flip-flop FF or FF 'low, whereby this flip-flop is reset and held in this state so that its output Q goes high again and this high level is again in the shift register SR or SR 'is pushed on by the clock gener a toi "CG. ¥ enn this high level arrives at the output of the shift register SR or SR ', the second input 2 of the third AND

Circuit G 'or G' high while its first input 1 was already high because Q of the F3.ipflop FF ₁ or FF 'was high. As a result, a negative pulse occurs at the output of the AND circuit G ₀ or G ', which resets the D flip-flop FF "or FF', whereby the second AND circuit G" or

G 'is closed and the level at its output changes. Because the output of the shift register SR or SR 'goes high again, the reset input of the bistable flip-flop FF ₁ or FF' also goes high and this flip-flop can be set again by a subsequent pulse.

Because both the falling and the rising edge of the signal at the input of the shift register SR or SR 'are used in conjunction with the shifting of the signal through the shift register SR or SR ¹ , it fulfills together with the flip-flop FF ₁ the funk- '

tion of the two monostable multivibrators of FIG. 4 and the time window circuit in connection with the delay line of Fig. 3 · It is evident that instead of one

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Shift register can also be used as a delaying element as a counter.

In Fig. 7 it is indicated Tile

a phase detector simply by means of two logic circuits consisting of bistable flip-flops with two inputs which can be set up on the falling edge of a signal at one input and reset from a low level at the second input and / or held in the reset state. The signal A coming from the upper half of the scanned track is sent to the reset input r of a bistable flip-flop FF and the set input ck of a bistable flip-flop FFr supplied. That from the lower half of the scanned The signal B originating from the track is on the one hand the reset input r of the flip-flop FF. and on the other hand the set input ck of the flip-flop FF supplied. ¥ enn the zero crossing of the signal from the upper half of the track arrives first, the flip-flop becomes FF. set and from the signal of the lower half the track whose zero crossing occurs later,

reset. Since the flip-flop FF "in the reset State is held, no pulse can occur at its output, while this can occur at the output Q of the flip-flop FF. is probably the case. However, if the zero crossing B of the signal from the lower half of the track arrives first,

the flip-flop FF »is set and reset by the zero crossing of the signal A of the upper half of the track so that a pulse occurs at its output. In this case, at the output Q of the flip-flop FF. no Signal occur.

The signal at the output of the flip-flop FF "is then used, for example, to move the head to the left to rotate while the signal at the output of the flip-flop FFr is used to move the playback head to the right

rotate in such a way that the error in the angular position 35

of the head is corrected.

In the examples described, it was assumed that the positive zero crossings

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of the signal can be used for regulation, but it stands to reason that it is also possible to do this with the negative To use zero crossings or even both types of zero crossings and in the latter case each type separately process and the output signals of the phase detectors assemble and feed the control device.

When playing two in stereo

For stereo tracks, it may be desirable to adjust the signals from both tracks, so that for each track

W a circuit according to Figures 3, 4 or 6 is available, the outputs of the two phase detectors via one logic circuit can be combined.

In Fig. 8, a magnetic tape 1 is shown, which in this case with two information

^ tracks 2 and 3 are provided, in which a stereo signal is recorded. These tracks are scanned with the aid of a stereo magnetic head k cooperating with the magnetic tape 1. The head h consists of a part 5 with a reading gap 7 »which scans the track 2, and a part 6 with

* a reading gap 8, which scans the track 3.

To the azimuth with respect to

determine tracks 2 and 3 from a phase relationship can, the parts 5 and 6 consist of two magnetic cores 9, 10 and 11, 12, which are the upper and lower halves of the

Scan tracks 2 and 3 separately.

Fig. 9 j in. The for the same

Parts as in Fig. 8 the same reference numerals are used, shows the further structure of the head h on the basis of a view of the section through the head according to Fig. 8 longitudinally

the line II-II. A short C-shaped core part 13 carries an electrical winding 14 and is arranged next to a long C-shaped core part 15 which carries an electrical winding i6. At an angle & to the core parts 13 and 15, a long C-shaped core part 17 is arranged,

which carries an electrical winding 18 and is arranged next to a short C-shaped core part 19, the one electrical winding 20 carries. To form more complete

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Cores that form a ¥ eg for the magnetic flux, which is closed except for the gap, can be the C-shaped core parts 13 »15» 17 and 19 to be assembled with core parts, which can also be C-shaped or I-shaped. In view of their small width (for the Application in a stereo cassette head 0.25 now) the special core parts each consist of a lamella of a soft magnetic alloy, e.g. a nickel-iron alloy, be made.

Claims (1)

December 20, 1978 V PHN 9136 C PATENT CLAIMS: 1. Method by which a slot of a playback head is brought into the correct angular position or held in this position with respect to a signal attached to a magnetic recording medium, in which the phase / difference between two sampled signals of the same shape is measured . a control signal for correcting the angular position of said gap is derived therefrom, i.e. characterized in that the scanned signals are obtained by, 1ö that simultaneously the upper half and the lower half of an information track to be reproduced are scanned separately will. 2. The method according to claim 1, characterized in that the time difference between two associated i \ ul! runs of the scanned Signals is measured. 3. The method as claimed in claim 1, characterized in that the signals to be scanned are each sent through a low meter whose cut-off frequency is lower than half the frequency that belongs to a signal whose period is equal to the size distance between two associated with the sampled signals.
H. Method according to claim 1, 9098 $ 0 / 064S ORSQIiMAL INSPECTED December 20, 1978 2 PHN 9136 C characterized in that the sampled signals be sent through a bandpass filter, whose Bandwidth is preferably equal to two octaves and its highest cutoff frequency is less than half the frequency that belongs to a signal whose period is equal to the maximum distance between two related zero crossings is} which frequency band is for. Audio applications preferably extends from + 2 to + 8 kHz. 5- method according to one of the standing claims, characterized in that the sampled signals depending on the filtering on the one hand over a first pulse shaper of a time window circuit and on the other hand via a threshold circuit with a threshold that is equal to or greater than the Rasch.voltage of the signal is fed to a second pulse shaper, after which it is determined whether the leading edge of this pulse falls within the time window, and if it does, an At the end of the time window generated pulse passed through a gate circuit ^ O being the sums of the tent durations of the time window and the generated pulse for both sampled signals are chosen to be the same, after which the generated pulses of both Channels are each fed to an input of a phase detector, the phase difference between the trailing edges associated generated impulses. 6. The method according to claims 1 to h, characterized in that, for stereo signals, each signal is fed via an associated control device to a logic circuit in which the control signals are combined. ( 7 Λ Device for performing the A method according to claim 1 provided with playback heads is fed to a phase detector for measuring the phase difference between the two of the playback- heads scanned signals of the same shape lead, the output of which is connected to a control device is connected to an electromechanical converter 909850/0645 December 20, 1978 3 'PHN 9136 C 1st who adjusts the angular position of the playback head can, characterized in that the playback head belonging to each track consists of two almost identical ones Parts for simultaneously scanning the upper half and the lower half of an information track to be reproduced consists. 8. Apparatus according to claim 7j, characterized in that each part of the playback head is connected to a low pass whose cutoff frequency is lower than half the frequency that belongs to a signal whose wavelength is equal to the greatest distance between two corresponding points of the Column of the two parts of the reproduction head it is in the Direction of movement of the recording medium measured. 9. Apparatus according to claim 7j characterized in that each part of the playback head is connected to a band pass filter whose Bandwidth is preferably equal to two octaves and its highest cutoff frequency is lower than half the frequency that belongs to a signal whose wavelength is equal to the maximum distance between two corresponding signals Points of the column of the two parts of the playback head, in the direction of movement of the record carrier measured which frequency band is for Audi ο extends from +2 to +8 IcHz applications. 10. Device according to claims to 9> characterized in that each part of the playback head üex- its associated filter on the one hand via a first pulse shaper with a time window circuit and on the other hand via a threshold circuit with a threshold that is equal to or greater than that Noise voltage of the signal is connected to a second pulse shaper, the output of which to a first Input of an AND circuit leads from a 35 second input to the output of the time window circuit is connected, which output also leads to the input of a delay line, the output of which 909850 / 0BiS 10.5.79 h pun 9136 c on the one hand with a first input of a second AND circuit and. on the other hand with the reset input of a Switching device is connected, the set input to the Output of the first AND circuit is connected, where 5 the output of the switching device to the second input the second AND circuit is connected, the output of which leads to an input of the phase detector, while the sums the duration of the time window of the time window circuit and the delay time of the delay line are practically the same for both channels. 11. The device according to claim 10, characterized in that the associated time- f ens test circuits and. Delay lines off each one and the same from a common RF clock generator 15th controlled delaying element exist. 12. The device according to claim 9> or 11, characterized in that the phase detector consists of two logic circuits with two inputs each, the output of which is on the trailing edge of a signal is set at the first input if the other input has a first logic level, and is reset or held in the reset state when the the other input has a second logic level, where the first input of the first logic circuit is 25 the second input of the second logic circuit and the first input of the second logic circuit with the second input of the first logic circuit is connected. 13 · Device according to claims 7 to 12, characterized in that in stereo playback there is a separate control device for each stereo track is, the outputs of the two phase detectors diesel 'control devices combined via a logic circuit will.
35 "\ h. Magnetic · playback head for Performing the method according to claims 1 to 6, characterized in that the reproducing head ₈ two adjacent 909850 / 0GiS 10.5-79. ■ 5 PHN 9136 C contains arranged magnetic cores, each provided with a playback gap and an electrical winding, wherein the display columns are aligned with one another and each have a width which is at most equal to half the width the information track to be read is 15 · Magnetic playback head after Claim 14, which is used for reading out stereo signals in two parallel information tracks lying next to one another suitable, characterized in that the magnetic head per 10 track contains a short and a long magnetic core, with the electrical winding of the long core in the in the direction perpendicular to the running surface of the head, lies under the electrical winding of the short core. i6 . Magnetic playback head after Claim 15j characterized in that the short and the long core of one of the two tracks in a first level and the short and long core of the other of the two tracks are in a "second level, which is connected to the first level encloses an angle θί. 20th 17 · Magnetic playback head after Claim 16, characterized in that each short core is parallel to the associated long core.