KR920002753Y1 - Magnetic recording device - Google Patents

Abstract

No content.

Description

Magnetic regeneration device

1 is a block diagram of one embodiment of the present invention.

2 is a signal waveform diagram in the main part of the present invention.

3 is a rotational head arrangement diagram of one embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1, 3, 5, 7: gap part for standard mode 2, 4, 6, 8: cap part for long time mode

9, 10, 11, 12: switching means 13, 14, 15, 16: preamplifier

A to D: double azimuth head

The present invention relates to a magnetic regeneration device, and more particularly, to a magnetic regeneration device capable of special regeneration such as fine throw / steel / search of a VTR.

A general VTR has special playback functions such as throw and still in addition to the normal playback function.

These special playback functions read the signals recorded on the magnetic tape by stopping the magnetic tape, for example in the case of stills. In this case, since the magnetic tape is not traveling, the rotating head scans the first and second tracks adjacent to each other.

However, the conventional magnetic regeneration device combines a preamplifier in a standard mode and a long time mode, and uses only a preamplifier for each mode. Therefore, since the first and second tracks adjacent to each other are recorded with rotation heads having different azimuth angles, the magnetic heads having one azimuth angle can read the tracks recorded with magnetic heads of opposite azimuth angles. And noise occurs.

In addition, the magnetic reproducing apparatus that generates such noise generates noise when it crosses over a track by selecting a reproducing signal having a large level among the reproducing signals amplified by a pre-amplifier installed independently of each magnetic head by a double azimuth head. It was configured not to. The apparatus of such a structure normally used one magnetic head of the two magnetic heads which comprise a double azimuth head as a standard mode head, and the other magnetic head as a head for a long time mode.

However, in the conventional magnetic regeneration apparatus, in order to perform special reproduction such as steel trough without noise, it is difficult to directly compare the output signals from the rotating heads, so that a preamplifier is required for each rotating head. There are problems such as high power consumption and high price.

The present invention has been made in view of the above-described object, and an object of the present invention is to provide a magnetic regeneration device capable of special reproduction with low power consumption and low noise at low cost.

The present invention detects that a preamplifier and a preamplifier output signal level for amplifying a reproduction signal from one magnetic head are lower than a predetermined level in either of the double azimuth heads, and detects from a detector and a detector for outputting a detection signal. A signal generator for generating a pulse signal having a predetermined pulse width in accordance with the magnetic tape traveling speed as an input of a signal, and is provided between the double azimuth head and the preamplifier and is pulsed by supplying a pulse signal from the signal generator. And switching means for supplying a reproduction signal from the other magnetic head to the preamplifier by switching the selection from one magnetic head to the other magnetic head that has been selected until then during the pulse width period of. .

For example, the magnetic head of one azimuth angle of the double azimuth head is selected as a switching means during special reproduction, and the reproduction output is taken out and amplified by a preamplifier. At this time, the preamplifier output signal is also supplied to the detector, and the output signal level gradually decreases when one magnetic head scans a track recorded by a rotating head having a different azimuth angle from the magnetic head. The detector detects that the output signal has fallen below a predetermined level and supplies a detection signal to the signal generation circuit.

The signal generation circuit receives the detection signal and supplies a pulse signal of a predetermined pulse width to the switching means in accordance with the traveling speed of the magnetic tape. The switching means selects such that when a pulse signal is supplied, a reproduction signal from the other magnetic head is output only in the pulse width period, and supplies the output signal to the preamplifier.

Therefore, the present invention detects switching of magnetic heads having different azimuth angles during special playback by lowering the output signal level below a predetermined level, so that the reproduction signals from the two magnetic heads of the double azimuth heads are shifted to one transpose. It can be amplified by an amplifier.

1 shows a block diagram of one embodiment of the present invention. A to D are double azimuth heads, 1 to 8 are each magnetic heads, 9 to 12 are switching means, and 13 to 16 are preamplifiers.

This embodiment is applied to a 270 DEG VTR, and the magnetic heads 1, 3, 5, and 7 are for the standard mode, and the magnetic heads 2, 4, 6, and 8 are for the long time mode. The magnetic head for the standard mode and the magnetic head for the long time mode are paired with different azimuth angles and have different track widths of the magnetic head.

Moreover, the arrangement | positioning on the rotating drum 24 of the double azimuth heads A-D is arrange | positioned every 90 degrees as shown in FIG. In normal playback, only the magnetic head of the mode corresponding to the recorded signal time mode is selected. The output signals of the double azimuth heads A to D are supplied to the preamplifiers 13 to 16, respectively, with the switching means 9 to 12 interposed therebetween, and after being amplified, the preamplifiers 13 to 16 by the switch 17. Switch the output signal as needed to output. The output signal of the switch 17 is supplied to the amplifier 18.

The amplifier 18 may change (equalize) the output characteristics depending on whether the input is from the magnetic head for the standard mode or the input from the cap for the long time mode for the long time mode, or the gain may be changed to be the same in both modes. At the time of special reproduction, the amplifier 18 outputs the output FM signal to a waveform, for example, the second diagram, and automatically adjusts its level to an appropriate value with the AGC amplifier 19 interposed therebetween. The output signal of the AGC amplifier 19 is demodulated by demodulation means (not shown) to form a reproduced video signal. In FIG. 2, the broken line shows the change in level when the telephone means are not switched.

In addition, the output FM signal of the amplifier 18 is supplied not only to the AGC amplifier 19 but also to the envelope detection circuit 20. The envelope detection circuit 20 envelopes the input FM signal from the amplifier 18 to form a waveform shown in FIG. 2B as a DC output signal, and supplies it to the comparator 21. In the comparator 21, in addition to the DC output signal from the envelope detection circuit 20, a trace hold control signal is externally inputted. When the DC output signal level becomes smaller than the threshold hold signal level, for example, the waveform shown in FIG. The pulse signal is output.

The output pulse signal of this comparator 21 is supplied to the mono multi vibrator 22. In addition to the pulse signal from the comparator 21, the tape speed information signal is input to the mono multi vibrator 22, and the time constant varies according to the reproduction speed.

For this reason, the mono multi-vibrator 22 outputs a pulse signal as shown in FIG. 2D only by the comparator 21 for a period in which the pulse signal is in accordance with the input drawing reproduction speed. The output signal of the mono multi vibrator 22 is supplied to the standard / long time mode switching circuit 23. In the normal reproduction, the standard / long time mode switching circuit 23 outputs a mode switching signal in accordance with the standard / long time mode selection signal from the outside and supplies it to the switching means 9 to 12 and the amplifier 18.

The switching means 9 to 12 have a pre-amplifier for reproducing signals from the magnetic heads 1, 3, 5, 7 for the standard mode or the magnetic heads 2, 4, 6, 8 for the long time mode according to the mode switching signal. 13-16). In addition, the amplifier 18 changes characteristics corresponding to each mode in accordance with the switching signal.

In addition, when the output pulse signal of the mono multivibrator 22 is supplied to the special reproduction, the standard / long time mode switching circuit 23 selects the period in which the output pulse report is supplied and the standard / long time mode selection signal from the outside. A switching signal is output, such as switching to a mode opposite to.

Next, the operation will be described in detail. For example, the case where special reproduction such as stills and troughs is performed in the standard mode will be described. Normal reproduction is performed with only the magnetic mode heads 1, 3, 5, and 7 for the standard mode, but during special reproduction such as steel trough, the same double azimuth head scans over the first and second tracks adjacent to each other. However, recording of neighboring tracks is performed at different azimuth angles.

For this reason, for example, if the magnetic head 1 having the same azimuth angle as the head recording the first track is scanned from the first track to the second track, the portion where the magnetic head 1 scans the first track is almost the same. Can be reproduced at a relatively high level, but since the portion scanning the first track decreases as the portion scanning the second track increases, the reproduction signal from the first track decreases slowly.

However, in this embodiment, when the level is lower than the predetermined value (the magnetic heads 1 and 5 scan the second track more, or the magnetic heads 3 and 7 scan the first track more. When a pulse signal D is generated, it is installed close to the magnetic heads 1, 3, 5, and 7, and is switched to the magnetic heads 2, 4, 6, and 8 for a long time mode with different azimuth angles, The track which the double azimuth heads A to D mainly scan is reproduced. For this reason, playback can be performed without degrading the level.

Similarly, in the case of special reproduction in the case of the magnetic tape recorded in the long time mode, the reproduction signal from the magnetic head for the standard mode can be selected and switched in accordance with the pulse signal generation, thereby reproducing without degrading the level.

In addition, the double azimuth head does not need to be constituted by the gap portion for the standard mode and the long time mode gap, and may be configured to have one side dedicated to special reproduction.

In addition, the switching means 9-12 may be provided on a rotating drum, or may be provided in another position. As in the embodiment, in a rotating drum of a small diameter, in which it is difficult to increase the number of rotary transformer channels compatible with a conventional rotating drum, it is necessary to increase the number of rotating heads without increasing the number of channels by providing a switching means on the rotating drum. This enables special playback without noise.

Further, the same can be done in the reproducing by the ordinary rotating drum wound up by 180 degrees.

As described above, according to the present invention, the double azimuth head is configured to compare the reproduction signal levels from two magnetic heads of different azimuth angles with a predetermined level, and one preamplifier for one double azimuth head. Since both amplified signals from one magnetic head can be amplified, special regeneration can be performed without installing a preamplifier for each magnetic head, and the number of preamplifiers can be reduced and power consumption can be reduced at the same time. It has such characteristics as.

Claims (1)

Two adjacent tracks on the magnetic tape approach each other's recorded magnetic tape signals so that the azimuth angles are different from each other.At the same time, a plurality of sets of double azimuth heads are used as a pair of two magnetic heads having different azimuth angles. In a magnetic reproducing apparatus for reproducing at a tape speed different from the normal reproducing speed, a preamplifier for amplifying a reproducing signal from one magnetic head in either of the pair of double azimuth heads and the output signal level of the preamplifier are at a predetermined level. The signal generator and the double azimuth which generate a pulse signal having a predetermined pulse width according to the tape traveling speed of the magnetic tape, which is detected by the detector which detects the lowering and outputs the detection signal and the detection signal input from the detector. Installed between the head and the preamplifier, the signal from the signal generator In the pulse width period of the pulse signal by supplying a switch signal, the selection switch is switched from one magnetic head selected from the one pair of the double azimuth heads to the other magnetic head to transfer the reproduction signal from the other magnetic to the preamplifier. And a switching circuit for supplying.