KR940008573Y1 - Auto-tracking circuit - Google Patents

Abstract

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Description

TRACKING CIRCUIT

1 is a block diagram showing a schematic configuration of an automatic tracking circuit according to the present invention.

2 is an exemplary embodiment showing the automatic tracking circuit of FIG.

3 shows the head drum traces a track of the tape.

* Real names of symbols on the main parts of the drawings

10: envelope waveform input means 20: comparison means

30: servo control means

The present invention relates to an automatic tracking circuit, and more particularly, to an automatic tracking circuit that allows a tape to be tracked automatically without the need to operate a tracking beaker in reproducing a videotape.

In general, VTR video signal recording dimension is very thin, track width is 0.2 ~ 0.02mm, recording wavelength is shortened to several micron, and stable recording control of drum rotation does not change the time axis of video signal during recording and playback. It is necessary to perform precise tracking control during regeneration so that degradation of the S / N ratio does not occur.

On the other hand, in order to maintain the tracking of video tracks during playback, it is necessary to maintain the drum rotation and the tape running state as in recording, so that framing control is performed to match the frame phase of the playback video signal to the frame phase of the reference synchronization signal. The phase comparison is performed between the reference frame pulse formed on the reference synchronization signal and the reproduced frame pulse separated from the reproduction signal of the control track.

The controlled oscillator is controlled by the phase-comparison pulse to change the phase comparison between the drum turk and the regenerative control signal, and the oscillator is controlled by this error voltage or the rotation speed is controlled by the capstan turk pulse. However, tracking adjustment using a conventional varactor adjusts the tracking by appropriately delaying the playback control signal. However, the tracking is slightly off depending on the condition difference such as the temperature or humidity during playback, resulting in noise or bits appearing on the screen. There was this.

Accordingly, an object of the present invention is to provide an automatic tracking circuit for reducing the inconvenience caused by the user's operation by automatically operating the tracking adjustment of the VTR in order to solve the above problems.

In order to achieve the above object, the present invention provides an envelope waveform input means for inputting an envelope waveform which is an image signal, direct current to an integrator, and applying the transistor waveform to the transistor Ql to drive the transistor Ql in comparison with a reference voltage Vref. And a comparator CP1 for inputting the output of the envelope waveform input means and outputting a maximum value of the signal level, and a comparator CP2 for driving the transistor Q4 by comparing the maximum value of the signal level with a voltage smaller than Vref. And a servo control means for connecting the transistor Q3 to the output of the comparison means and applying an output signal of the envelope waveform input means to conduct the transistor Q2 to input a tracking voltage to the servo terminal. It is characterized by.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a schematic configuration of an automatic tracking circuit according to the present invention. The envelope waveform input unit 10 inputs an envelope waveform B, which is an image signal, to convert a DC voltage into a resistor and a capacitor constituting an integrator. The transistor Q1 is driven by comparing the Vcc voltage applied to the base of Q1 with the Vref divided by the resistor, and the comparing means 20 makes the transistor Q1 constituting the envelope waveform input means 10. And a comparator CP2 for driving the transistor Q4 by comparing the maximum value of the signal level with a voltage smaller than Vref by introducing a base voltage of The transistor 30 applies the collector voltage of the transistor Q1 constituting the envelope waveform input means 10 by interlocking the transistor Q3 when the transistor Q4 of the comparison means 20 conducts. By conducting a W transistor (Q2) and the input voltage to the tracking standing than (S).

FIG. 2 shows an exemplary embodiment of the automatic tracking circuit according to FIG. 1, in which the envelope waveform B of the frequency modulated signal is input to the envelope waveform input means 10, thereby providing resistors R5 and R6 and a capacitor C1. Integrate by the integrator, and apply a constant DC voltage at point C to the base of transistor Q1.

At this time, when the reference voltage Vref of the A point is +0.7 V or more higher than the C point potential, the transistor Q1 is "turned on" so that the D point potential plus +0.7 V is applied to the port of the servo control means 30. By controlling the servo motor and inputting the level signal of the frequency modulation captured from the head drum to point B, the DC potential appearing at point C becomes high and becomes Vc (potential at point C)> Vref −0.7 (V). Q1 and Q2 are " turned off " so that the D point potential is not applied to the servo terminal. Therefore, the servo phase control is stopped and the status is maintained at this time. In other words, when the waveform inputted to the B contact becomes the maximum (when the head drum traces the track properly), it is not necessary to change the servo tracking by making Vc> Vref -0.7 (V). ) To maintain the tracking center.

On the other hand, if the head drum makes an abnormal trace as shown in Fig. 2 (2) showing the head trace state beyond the track position of the tape, the frequency modulation signal level of the envelope captured by the head drum is Vc <Vref-0.7 ( V) and the transistors Ql and Q2 are " tinned on " so that the authenticity of D is input to the servo terminal. At this time, tracking adjustment is performed until the trace of the head drum becomes more than Vc≥Vref-0.7 (V). As a result, when the head traces the tape normally, the envelope level becomes Vc &gt; Vref-0.7 (V), so the transistors Q1 and Q2 are " off &quot; to stop the tracking control operation.

The comparator CP1 function of the comparing means 20 outputs the maximum signal level of the tape to the point F, and the point E of the maximum signal level (envelope level) of the tape currently being used divides the Vcc voltage into the resistors R8 and R9. If the potential is lower than the potential (Vref-0.7 (V)), the G contact output becomes the "low" potential by the action of the comparator CP2, and the transistors Q4 and Q3 are "turned on" and the H-fold authenticity is "low" do. At this time, the D point potential is not applied to the servo terminal S, making tracking control impossible. In addition, in a multi-function mode (high state) such as still and picture search other than normal playback, the transistor Q3 is operated by receiving the "high" input signal at the point I of the servo control means 40 to lower the potential at the point H. "To disable automatic tracking.

As described above, the present invention has an advantage of preventing excessive power consumption by inducing the use of an optimum state in an industrial device burner or a home air conditioner or the like as well as VTR by automatically tracking by servo control.

Claims (1)

An envelope waveform input means for inputting an envelope waveform, which is an image signal, and direct-current to an integrator, and applied to a transistor Ql to drive the transistor Ql in comparison with a reference voltage Vref, and an output of the envelope waveform input means. A comparator composed of a comparator (CP1) for drawing in and outputting a maximum value of the signal level, and a comparator (CP2) for driving the transistor (Q4) by comparing the maximum value of the signal level with a voltage smaller than Vref; And a servo control means for interlocking a transistor (Q3) as an output to apply an output signal of the envelope waveform input means to conduct a transistor (Q2) to input a tracking voltage to a servo terminal.