KR860001842B1 - Rotating head and control circuit for video tape recorder - Google Patents

Abstract

This invention involves the reproduction signal recorded on magnetic thin film, where the rotating part of a drum is coated with magnetic thin film that prevents the noise signal from occuring during the varying speed reproduction. By using a magnetic film, the external moniter shows a fine screen which does not contain noise signals. The rotating controller of VTR consists of a switching signal generator and a video signal switch. The switching signal generator in Fig. 4 is composed of a pulse GENERATOR, FLIP-FLOPS, A COUNTER, A MONOMULTI, AN INVERTER, and GATES, an ORGATE and an EX-OR GATE.

Description

Rotating drum of video tape recorder with magnetic film and its control device

1 is a longitudinal sectional view of the rotating drum of the present invention.

2 is a sectional view taken along the line A-A of FIG.

3 is a block diagram for explaining the control device of the present invention.

4 is a detailed circuit diagram of FIG.

5 is an output waveform diagram of each part of FIG.

* Explanation of symbols for main parts of the drawings

2: drum motor 3: rotating drum

4a, 4b: rotating head 5: fixed head support

6a, 6b: fixed head 7: magnetic film

8: tape 12, 13, 17, 18: head amplifier

14,19: head switch switch 15: recording / playback area switch

15a, 15b, and 15c: movable terminals of the recording / reproducing area changeover switch 15

19a: operation terminal 16 of head changeover switch 19: recording amplifier

20: P-video signal switch 21: radio frequency level detector

22: switching signal generator 23: pulse generator

24: Exclusive Oagate 25, 26, 27, 35, 36: Flip-flop

28: counter 30: monomulti

31: inverter 32, 33, 34: end gate

37: Oagate

According to the present invention, a magnetic film is provided on the rotating part of a drum of a video tape record, and the magnetic film is attached to the magnetic film to record and output a signal during tape playback of the video tape record, thereby preventing the noise signal during shift playback. BD. A rotating drum of a tape record and a control device thereof.

In the conventional video tape record, in order to output a clean video signal without noise signal by shifting and playing the track of the tape on which the video signal is recorded, the video head must accurately adjust the movement of the tape. There were various problems, such as the need to install a separate dedicated head with the same azimuth angle.

In view of the above, the present invention investigates the magnitude of the radio frequency (RF) signal of the signal reproduced by the rotating head to prevent the noise generated during the shift reproduction. When the signal is above the reference level, that is, when the signal is a clean field, it is recorded on the magnetic film installed in the drum's rotating part, and during the period when the noise signal is output from the rotating head, the signal already recorded on the magnetic film is reproduced and output. The monitor has been invented so that a clean screen without noise is outputted at any speed reproduction. The detailed description will be given below with reference to the accompanying drawings.

FIG. 1 is a longitudinal sectional view of the rotating drum of the present invention, and FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1, and as shown therein, the lower fixed drum 1 is installed and the drum drum 2 rotates the drum 3. A rotating drum device for recording and reproducing video tape records in the rotating heads 4a and 4b provided in the rotating drum 3 by rotating the rotating head 3, wherein the fixed head is spaced at a small interval above the rotating drum 3. Fixing heads (5) are provided on the lower surface of the fixed head support (5), and the fixing heads (6a) and (6b) are mounted on the upper surface of the rotating drum (3) facing the fixing heads (6a, 6b). The magnetic film 7 is formed in the circumferential direction so that the magnetic film 7 also rotates with the rotation of the rotating heads 4a and 4b to record and reproduce the video signal on the magnetic film 7.

This will be described with reference to FIG. 3, which is a block diagram of the control device of the present invention. If the green / green signal is applied to the recording / playback changeover signal to the recording / playback changeover switch 10 when the normal speed is operated, the recording / playback switch 10 enters the recording state. (11) and the recording / playback switch 10 to be applied to the rotary heads 4a and 4b and recorded on the tape 8 in a helical manner according to the rotation of the rotating drum 3, and recording / playback When a playback signal is applied among the recording / playback switching signals to the switching switch 10, the recording / playback switching switch 10 is brought into the playback state, and the signal recorded on the tape 8 is rotated according to the rotation of the rotating drum 3. The signals detected by 4a) and 4b and the signals detected by the rotating heads 4a and 4b are amplified by the head amplifiers 12 and 13 through the recording / playback switching switch 10, respectively, and then the image heads. Which head amplifier 13 and 13 outputs the video signal output from the head changeover switch 14 according to the switching signal? In the rotating drum control apparatus for a video tape record which is determined and output to the video signal processing system, when the shift start signal and the sampling request signal are applied to the switching signal generator 22, the switching signal generator 22 is connected to the rotating head 4a, Blocking the video signal reproduced at 4b and output from the head changeover switch 14 to the video signal processing system, and simultaneously recording the video signal to the recording amplifier 16 and the recording / reproducing area changeover switch 15 It is applied to the fixed head 6a or 6b in accordance with the head switching signal, and is recorded in one side region 7a or the other side region 7b of the magnetic film 7, and also in one side region 7a of the magnetic film 7. ) Or after detecting the video signal recorded in the other area 7b with the fixed head 6a or 6b, the head amplifiers 17, 18 and the head changeover switch 19 and the video signal changeover switch 20 Through the video signal processing system. If a noise signal is included in the video signal output from the head changeover switch 14, the signal is detected by the radio frequency level detector 21 and applied to the switching signal generator 22 so that the switching signal generator 22 switches the recording / reproducing area. Signals are sent to the switch 15 and the head changeover switch 19 to reproduce the video signals in the one region 7a or the other region 7b of the magnetic film 7 recorded just before, so that the head amplifiers 17, 18 And the head change switch 19 and the image signal switch 20 to be output to the video signal processing system. This is configured to output to the outside, which will be described with reference to FIG. 4, which is a detailed circuit diagram of FIG. 3, and FIG.

The video head switching signal is connected to one side of the input terminal of the pulse generator 23 and the exclusive oragate 24, which are composed of the monomulti 23a, 23b, the inverter 23c, and the oragate 23d. The output side of the pulse generator 23 is connected to the input terminals T, T, S, T, and the counter 28 of the flip-flops 25, 26, 27, and 29. The input terminal CK is connected to the input side of the motor multi 30, and the shift start signal is an input terminal J of the flip-flop 25 and an output terminal connected to the input terminal R of the counter 28. It is connected to be applied to one input terminal of the gate 37, and the sampling request signal is connected to be applied to the input terminal J of the flip-flop 26. In addition, the output side of the radio frequency level detector 21 connected to the output side of the head changeover switch 14 is the other side of the AND gate 32 through which the one input terminal is connected to the output side of the monomulti 30 through an unverter 31. The output terminal D of the counter 28 is connected to the other input terminal of the oragate 37 and the input terminal R of the flip-flop 27, and the output terminal D of the counter 28 is connected to the input terminal. It is connected to the input terminal K, and its output terminal Q is connected to one input terminal of the AND gate 25, and its output terminal Q is input to the flip-flops 26, 29, 36. Terminals R, R, and R, and the output terminals Q and Q of the flip-flop 27 are connected to the input terminals J and K of the flip-flop 29, respectively. Its output terminal Q is connected to the other input terminal of the end gate 33 whose one input terminal is connected to the output terminal Q of the flip flop 26, and the output side of the end gate 33 is a flip flop ( 26), 35) input terminals (K), (T) and end The output terminal Q of the flip-flop 35 is connected to the other input terminal of the exclusive 34, and the output side of the AND gate 34 is connected to the other input terminal of the flip-flop 35. The switching signal generator 22 is constituted by connecting to the input terminal S of the terminal 36).

The output terminal Q of the flip-flop 36 of the switching signal generator 22 configured as described above is connected to the video signal switching switch 20, and the output side of the exclusive 24 is a recording / reproducing region switching switch using transistors. 15 are connected to the movable terminals 15a, 15b, 15c and the movable terminal 19a of the head changeover switch 19, and the output side of the head changeover switch 14 is connected via the recording amplifier 16. the fixed contacts of the movable terminal (15a), (15b) fixed contacts (a _1), connected to (b _2), and the movable terminal (15a) is movable terminal (15c) through the fixed head (6a) of (a ₃₎ and and connected to an input side of the head amplifier 17, a movable terminal (15b) is connected to the input side of the fixed contact point (b ₃₎ and the head amplifier 18 of the movable terminal (15c) through the fixed head (6b) and movable The fixed contacts a ₄ and b ₄ of the terminal 19a are connected to both ends of the resistors 19b and 19c and the variable resistor 19d connected to the outputs of the head amplifiers 7 and 18, respectively. The intermediate step 15 of the variable resistor 20 is converted into a video signal switch. Constitute by accessing the value (20).

Here, the movable terminals 15a, 15b, 15c of the recording / reproducing area changeover switch 15a and the movable terminal 19a of the head changeover switch 19 are interlocked with each other. If the output signal of 24 is in the low potential state, it is short-circuited to the fixed contacts (a ₁ ), (a ₂ ), (a ₃ ), and (a ₄ ), respectively, and the output signal of the exclusive oragate 24 is high potential. If each state is short-circuited to the gojeop peak _{(b 1), (b 2} ), (b 3), (b 4).

According to the present invention, when the shape head switching signal is applied to the head changeover switch 14 from the drum servo circuit as shown in FIG. 5 (a), the head amplifier 12 is regenerated in the rotating heads 4a and 4b. The signal amplified by (13) is converted by the head changeover switch 14 to be outputted, and at this time, the output signal Q is low at the output terminal Q of the flip-flop 36 of the switching signal generator 22 as described below. When the potential signal is output, the signal output from the head changeover switch 14 is output to the video signal processing system through the video signal changeover switch 20.

On the other hand, as the image head switching signal is applied to the pulse generator 23, an output waveform (hereinafter referred to as a clock pulse) as shown in FIG. 5 (b) is generated and output on the output side thereof, and the clock pulse is flip-flop ( 25, 26, 27, 29 input terminals T, T, S, T and counter 28 of input terminal CK, motor multi 30 It is applied to the input side. Accordingly, the high potential signal is output to the output side of the monomulti 30 at the time when the clock pulse output from the pulse generator 23 falls, as shown in FIG. 5 (c), to maintain the high potential state for a predetermined time. In this state, when a shift start signal as shown in FIG. 5 (d) is applied (t ₁ ), a high potential signal as shown in FIG. 5 (f) is output to the output side of the oragate 37 to counter 28 Since the counter 28 is reset, the low potential signal is output to its starter D as shown in fifth (g), and the low potential signal is flip-flop (). 25 is applied to the input terminal K, and since the shift start signal of the high potential state is applied to the input terminal J thereof, the next clock is output from the pulse generator 23 to the output terminals Q and Q. At the time t _{2 at} which the pulse is generated, the high potential signal and the low potential signal as shown in the fifth (h) and fifth (i) degrees are output, respectively. However, before the sharpening request signal is applied to the input terminal J of the flip-flop 26, a low potential is output to the output terminal Q of the flip-flop 26, and is supplied to one input terminal of the AND gate 33. Since it is applied, a low potential signal such as the fifth (n) degree is output to the output side of the AND gate 33. Since the low potential signal is applied to the input terminal T of the flip-flop 35, the low potential signal is output to the output terminal Q thereof and is applied to the other input terminal of the exclusive oar gate 24 so that it is exclusive. The high potential signal is output to the output side of the oragate 24 only when the video head switching signal input to one input terminal is in the high potential state. However, at this time, since the video head switching signal is in a low potential state, a low potential signal is output to the output side of the exclusive oragate 24, and accordingly, the movable terminals 15a (, 15b) ( 15c) and the movable terminal 19a of the head changeover switch 19 are short-circuited to their fixed contacts a ₁ , a ₂ , a ₃ , and a ₄ , respectively, and are output from the head changeover switch 14. The video signal flows to the ground through the fixed contact a ₁ of the recording amplifier 16 and the movable terminal 15a, the fixed head 6a, and the fixed contact a ₃ of the movable terminal 15c. The signal amplified by 16 is recorded in the uniaxial region 7a of the magnetic film 7 by the fixed head 6a. At this time, the fixed contact a ₂ of the movable terminal 15b is the fixed head 6b, the head amplifier 18, the resistor 19c, the variable resistor 19d and the fixed contact a ₄ of the movable terminal 19a. Since the video signal recorded in the other region 7b of the magnetic film 7 is reproduced by the fixed head 6b and amplified by the head amplifier 18, the amplified signal by the head amplifier 18 The intermediate resistor of the variable resistor 19d is applied to the video signal switching switch 20. However, at this time, since the low potential signal output to the output side of the AND gate 33 is applied to the other input terminal of the AND gate 34, a low potential signal such as the fifth (p) is output to the output side thereof, so that the flip-flop 36 Since the low potential signal is output to the video terminal switch switch 20, the low voltage signal is output to the output terminal Q of the flip-flop 36. Blocking the video signal output from the 19) and outputs the video signal output from the head switching switch 14 to the video signal processing system.

In this state, when the sampling request signal is applied to the input terminal J of the flip-flop 26 at the time t ₃ as shown in FIG. 5 (e), the pulse generator (i) is applied to the output terminal Q of the flip-flop 26. At a time t ₄ when the next clock pulse is generated at 23), a high-potential signal such as the fifth (j) is output and applied to one input terminal of the AND gate 33. In addition, the radio frequency level detector 21 detects a video signal output from the head changeover switch 14, and if the video signal includes a noise signal, outputs a low potential signal to the output side thereof. When the high potential signal is output to the output side of the radio frequency level detector 21 because the video signal does not include a noise signal at the output side thereof, the high potential signal is low potential at the inverter 31. Since the signal is inverted and applied to the input terminal of the AND gate 32, a low potential signal is output to the input terminal R of the flip-flop 27 as shown in FIG. 5 (k). Therefore, a high potential signal such as the fifth (l) degree is output to the output terminal Q of the flip-flop 27 and applied to the input terminal J of the flip-flop 29, so that the next clock pulse is generated by the pulse generator 23. At a generated time t ₂ , a high potential signal, such as the fifth (m), is output to the output terminal Q of the flip-flop 29 and applied to the other input terminal of the AND gate 33. Accordingly, when the high potential signal is output from the output terminal Q of the flip-flop 26, the sampling signal indicating that the high-frequency potential is output to the output side of the AND gate 33 as the fifth (n) is detected to detect the correct sampling signal. Since the high potential signal outputted from the AND gate 33 is applied to the input terminal T of the flip-flop 35, its output signal is inverted and the output terminal Q thereof has a fifth (o). A high potential signal is output as shown.

Accordingly, the high potential signal is output to the output side of the exclusive oragate 24 only when the head switching signal is in the low potential state, and at this time, the high potential signal output from the AND gate 33 is input to the other side of the AND gate 34. A high potential signal is applied to one terminal of the end gate 34 of the AND gate 34, and a high potential signal output from the output terminal Q of the flip-flop 25 is applied to the output side thereof. The signal is output and applied to the input terminal S of the flip-flop 36. Accordingly, the high-potential signal is output to the output terminal Q of the flip-flop 36 as shown in FIG. Since it is applied to the video signal switch 20, the video signal output from the head switch switch 14 is output to the processing system. However, at this time (t _4- t ₅ ) since the video head switching signal is in a high potential state and a low potential signal is output to the output side of the exclusive oar gate 24, the movable terminal 15a of the recording / reproducing area changeover switch 15 is provided. , 15b, 15c and the movable terminal 19a of the head changeover switch 19 are short-circuited to its fixed contacts a ₁ , a ₂ , a ₃ , and a ₄ , and at this time, Since the magnetic film 7 is located at the fixed head 6b and its other region 7b is located at the fixed head 6a, the magnetic film 7 is output from the head changeover switch 14 and amplified by the recording amplifier 16 as described above. Since the video signal is located at the fixed head 6a, the video signal outputted from the head changeover switch 14 and amplified by the recording amplifier 16 is the other region of the magnetic film 7 through the fixed head 6a. At the same time as the image signal recorded in (7b) and recorded in one side area 7a of the magnetic film 7, the image signal is reproduced in the fixed head 6b and then the head amplifier 18, the resistor 19c, and the variable resistor 19d. And an image signal processing system through the image signal switching switch 20. In addition, since the high potential signal output from the AND gate 33 is applied to the input terminal K of the flip-flop 26, the time t at which the next clock pulse is generated by the pulse generator 23 at the output terminal Q thereof. ₅ ) and a low potential signal is applied to the input terminal of the AND gate 33 so as to output a low potential signal as shown in FIG. The high potential signals are continuously output to the pull terminals Q and Q of the Robs 35 and 36 as shown in the fifth (o) and the fifth (q) to maintain the above operation.

If a noise signal is included in the video signal output from the head changeover switch 14 in this state, it is detected by the radio frequency level detector 21 and a low potential signal is output to the output side thereof. Since the signal is inverted to the high potential at and applied to the other input terminal of the AND gate 32, a pulse signal is generated at the output side thereof as shown in fifth (k) and applied to the input terminal R of the flip-flop 27. Accordingly, since the low potential signal is output to the output terminal Q of the flip flop 27 and the high potential signal is output to the output terminal Q, the output terminal Q of the flip flop 29 is output. At the time t ₆ at which the next clock pulse is output from the pulse generator 23, a low potential signal is output as shown in the fifth (m). In addition, since the low potential signal output from the AND gate 33 at the time t ₅ is applied to the input terminal K of the flip-flop 26, the time t ₆ when the next clock pulse is output from the pulse generator 23. A high potential signal is output to its output terminal Q as shown in FIG. 5 (j) and applied to one input terminal of the AND gate 33, but at this time (t ₆ ), the output terminal of the flip-flop 29 Since the low potential signal output at (Q) is applied to the other input terminal of the AND gate 33, the low potential signal is output to the output side thereof.

Therefore, the output terminals (Q) and (Q) of the flip-flops (35) and (36) maintain high potentials, and thus high potentials only when the head switching signal of the exclusive oragate 24 is in the low potential state. Will output a signal. However, since the video head switching signal is in the low potential state at the time t ₅ , a high potential signal is output to the output side of the exclusive oar gate 24 to enable the movable terminal 15a of the recording / reproducing region switching switch 15, 15b, 15c and the movable terminal 19a of the head changeover switch 19 are short-circuited to their fixed contacts b ₁ , b ₂ , b ₃ , and b ₄ , and at this time, The film formation 7 is rotated so that its one side area 7a is located at the fixed head 6a and its other area 7b is located at the fixed head 6b, so that the magnetic film 7 is recorded in the one area 7a. The normal video signal is reproduced by the fixed head 6a and output to the video signal processing system as described above, and at this time, the video signal including the noise signal is output from the changeover switch 14 as described above. In the other region 7b of the magnetic film 7 through? In addition, since the low potential signal is output to the output terminal Q of the flip-flop 29 as shown in FIG. 5 (m) until the time t ₇ when the next clock pulse is generated in the pulse generator 23, the AND gate 33 On the output side, the low potential state as described above is maintained.

However, at the time t ₆ , since the head switching signal is in the high potential state, the low potential is output to the output side of the exclusive oar gate 24 so that the movable terminals 15a, ( 15b) and 15c and the movable terminal 19a of the head changeover switch 19 are short-circuited to their fixing points a ₁ , a ₂ , a ₃ and a ₄ , and at this time, the magnetic film (7) is rotated so that its one side area 7a is located at the fixed head 6b and its other area area 7b is located at the fixed head 6a, so that it is recorded in one area 7a of the magnetic film 7. The normal video signal is reproduced in the fixed head 6b and recorded in the other region 7b of the magnetic film 7 through the fixed head 6a as described above. In the pulse generator 23, a high potential signal is output to the output terminal Q of the flip-flop 29 as shown in the fifth (m) at the time t ₇ when the clock pulse is generated, The high potential signal is output to the output side, and accordingly, the output signal of the flip-flop 35 is inverted and the low potential signal is output to the output terminal Q thereof. At this time, the high potential signal output from the AND gate 33 is applied to the input terminal K of the flip-flop 26, and the time t at which the next clock pulse is generated by the pulse generator 23 at its output terminal Q. ₈ ) the low potential signal is output as shown in FIG. 5 (j), but the signal output from the output terminal Q of the flip-flop 35 maintains the low potential state as described above. Therefore, since the head switching signal is in the low potential state at time t ₇ , the low potential signal is output to the output side of the exclusive oar gate 24 so that the movable terminals 15a and 15b of the recording / reproducing area changeover switch 15 are provided. ), 15c and the movable terminal 19a of the head changeover switch 19 are short-circuited to the fixed contacts a ₁ , a ₂ , a ₃ , and a ₄ , and at this time, the magnetic film ( 7) is rotated so that its one side area 7a is located at the fixed head 6a and its other area 7b is located at the fixed head 6b, so that the normal video signal recorded in the other area 7b as described above. The normal image signal output from the fixed head 6b is recorded in one region 7a of the magnetic film 7 through the fixed head 6a.

In this state, when the sampling request signal is blocked as shown in FIG. 5 (e) and the shift start signal is blocked as shown in FIG. 5 (d), and enters the normal playback state, the low potential is applied to the other input terminal of the oragate 37. A signal is applied, and at this time, the video signal output from the head changeover switch 14 is in a normal reproduction state so that there is no noise signal. Therefore, a low potential signal is continuously output to the output side of the AND gate 32 so that the oragate 36 is turned off. The low-potential signal is continuously output to the input terminal R of the counter 28 as shown in FIG. 5 (f) and applied to the input terminal R of the counter 28, so that the counter 28 pulses. After counting the clock pulses output from the generator 23 by a set number, a high potential signal is output to the output terminal D thereof as shown in fifth (g), and the high potential signal is input to the flip-flop 25. Is applied to the (K) pulse generator ( At the time t ₉ at which the next clock pulse is generated at 23), a low potential signal is output at its output terminal Q as shown in FIGS. 5 (h) and 5 (i), and at its output terminal Q. A high potential signal is output. Therefore, the high potential signal output from the output terminal Q is applied to the input terminals R, R, and R of the flip-flops 26, 29, and 36, so that the output terminals Q and The low potential signal is output to (Q) and (Q) as shown in the fifth (j), the fifth (m), and the fifth (q), and the low potential output to the output terminal (Q) of the flip-flop (36). Since the signal is applied to the video signal changeover switch 20, the video signal reproduced in the fixed head 6a or 6b as described above to block the video signal output from the head changeover switch 19 and at the same time the head changeover switch 14 ) Outputs the video signal output to the video signal processing system.

Therefore, even in the transitional part in which the speed is changed from the shift reproduction state to the normal reproduction state, it is possible to output a normal video signal not including a noise signal.

As described above, the present invention records the video signal output from the head switching switch 14 after being reproduced by the rotary heads 4a and 4b during the shift reproduction to the fixed heads 6a and 6b for recording and reproducing. By recording and playing back on the magnetic film 7 and outputting it to the image processing system, it is possible to output clean image signals while continuously changing the speed from -1x reverse playback to 3x speed. If the running speed of the tape is lowered momentarily until the sampling request signal is sent and the sampling signal is output, a clean video signal can be recorded on the magnetic film 7 and output. Clean shift reproduction is possible.

Claims (3)

A rotating drum device of a video tape recorder, which records and plays back at the rotating heads 4a and 4b provided on the rotating drum 3 by rotating the rotating drum 3 with the drum motor 2, wherein the rotating drum ( 3) The fixed head support 5 is installed at a predetermined interval on the upper part, and fixed heads 6a and 6b are installed on the lower surface of the fixed head support 5, but the fixed heads 6a and 6b are provided. The magnetic film 7 is formed in the circumferential direction of the upper surface of the rotating drum 3 opposite to the recording head, and the recording signal is reproduced and reproduced in the magnetic film 7 together with the rotation of the rotating heads 4a and 4b. A rotating drum device for a video tape recorder with a magnetic film. The video signal recorded on the tape according to the recording / playback switching signal is reproduced by the rotating heads 4a and 4b and output to the video signal processing system through the head switching switch 14 in accordance with the video head switching signal. In the rotating drum control apparatus, when the shift start signal and the sampling request signal are applied, the detection signal and the video head switching signal of the radio frequency level detector 21 for detecting the level of the video signal output from the head changeover switch 14 are applied. The switching signal generator 22 generating the switching signal and the image signal output from the head changeover switch 14 are applied to the fixed head 6a or 6b according to the switching signal of the switching signal generator 22 described above. The image signal recorded in one region 7a or the other region 7b of the magnetic film 7 and recorded in one region 7a or the other region 7b of the magnetic film 7 is fixed head 6a or Output by playing at 6b The video signal output from the head changeover switch 14 is outputted to the video signal processing system according to the recording / reproducing area changeover switch 15 and the head changeover switch 19 and the switching signal of the switching signal generator 22 described above. And a video signal switching switch 20 for outputting the video signal outputted from the head switching switch 19 to the video signal processing system at the same time. The switching signal generator 22 is a pulse generator (23), flip-flops (25), (26), (27), (29), (35), (36), counter (28), Mono magnetic 30, inverter 31, end gates 32, 33, 34, oragate 37 and the exclusive oragate 24 is attached Control device for rotating drums of video tape recorders.

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