KR910006342Y1 - Auto tracking circuit of v.t.r. - Google Patents

Abstract

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Description

VTR Auto Tracking Circuit

1 is a conventional circuit diagram.

2 is a circuit diagram of the present invention.

3 is a characteristic curve diagram of the FET.

* Explanation of symbols for main parts of the drawings

10: envelope detector 20: control signal generator

30: servo control unit C1-C7: capacitor

R1-R15: resistor VR1: variable resistor

Q1-Q4: Transistor Q5: FET

L1-L2: Coil CMP: Comparator

The present invention relates to a tracking control circuit of a VTR, and more particularly to a circuit that can detect an envelope of a video signal and automatically control tracking according to the change.

In general, depending on the type of VTR (Video Tape Recorder), each control pulse has a slight time delay.

The control pulse is a signal recorded in a control track on a magnetic tape by a control head, and is used as a reference signal of a servo system during reproduction.

Therefore, if the above control pulse has a slight time delay depending on the type of VTR, the magnetic tape cannot pick up the correct track when it is played back in a VTR other than the recorded VTR.

As a result, noise is generated on the screen during reproduction. In order to solve this problem, tracking is performed by attaching a variable resistor to the outside in the same manner as in FIG.

In general, noise is generated on the screen when the time delay between the head switching pulse and the control pulse during playback is greater than 6.5H (Hihorizontal Sync). When the user manually adjusts the variable resistor VT1 when the noise occurs, the signal is applied to the tracking mono-multi circuit inside the servo circuit. Change.

At this time, if the variable resistance value is adjusted to the best part of the screen, the tracking is correct.

However, the tracking adjustment method as described above has a cumbersome problem because the user has to manually adjust the tracking by manually adjusting the variable resistor when playing the tape (manual tracking).

Therefore, the present invention provides a circuit that detects an envelope of a carrier frequency of a video RF signal and compares this voltage with a predetermined reference voltage and automatically adjusts tracking using the voltage difference.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 2 is a specific diagram of the present invention, which is composed of capacitors C1-C6, resistors R1-R15, coils L1-L2, and transistors Q1-Q4, and displays a video RF signal reproduced through a head. An envelope detector 10 for generating a DC power supply by detecting the envelope of this signal after amplification, and comprises a comparator CMP, a FET Q5, a variable resistor VR1, and a capacitor C7 to track the DC power supply. And a control signal generator 20 for generating a tracking adjustment signal according to the voltage difference compared to a predetermined reference voltage for adjustment, and a servo controller 30 for automatically adjusting tracking according to the tracking adjustment signal.

FIG. 3 is a characteristic curve diagram of the FET in FIG. 2 and shows a linear characteristic of the output current IDS with respect to the input voltage VGS.

Based on the above-described configuration will be described in detail the present invention with reference to the drawings.

The video RF signal reproduced through the head is applied to the base of the transistor Q1 through the coupling capacitor C1. Here, a bipolar transistor is referred to as a transistor and a field effect transistor is referred to as a FET. At this time, the video signal is picked up to 5.9 MHZ by the coil L1, the capacitor C2 and the resistors R4 and R5 connected to the emitter terminal of the transistor Q1 and output to the collector terminal of the transistor Q1.

The output of the transistor Q1 is buffered through the transistor Q2 and output to the emitter stage. The signal is converted into a low pass filter by the input impedance values of the capacitor C3, the resistors R9 and R10, and the transistor Q3. The low pass filter is applied to remove the low frequency components of the color crosstalk signal and the FM modulated luminance signal. The signal is again picked up at 4MHZ through resistor R14, capacitor C4, coil L2 and transistor Q3. That is, in the VHS method, the white peak is 4.4MHZ and the sync tip is 3.4MHZ. Therefore, the luminance signal is FM-modulated with a frequency deviation of 1MHZ and then recorded on the tape. Therefore, the 4MHZ signal picked up by the transistor Q3 becomes the FM carrier frequency of the VHS method. Thereafter, the signal is charged and discharged again by the resistor R15 and the capacitor C6 through the transistor Q4 to have a constant DC voltage value. In this case, the resistor R15 should be appropriately selected so that the discharge time is not too short. .

After amplifying the video signal reproduced through the head as described above, the envelope of the carrier frequency is detected from the signal, thereby generating a DC voltage. In the present invention, the envelope detection signal is compared with a predetermined reference voltage. An output corresponding to the voltage difference is generated and applied to the servo controller 30 as an auto tracking adjustment signal.

Therefore, the DC voltage value is applied as a comparison signal of the comparator CMP, and a predetermined reference voltage value is applied as a reference signal of the comparator CMP. Value.

Accordingly, the comparator CMP generates a difference signal between the DC voltage value generated by the envelope detection and the reference voltage value, and the difference voltage is connected to a gate terminal of a metal oxide semicondutor FET (MOS FET) F5. Is approved. Since the output current IDS is linearly changed as shown in FIG. 3 according to the voltage VGS between the gate and the source, which is an input voltage, the FET F5 is linearly changed. The output of the FET F5 is applied to a tracking multi-meno circuit of the servo control unit 30, and the FET F5 is the servo control unit 30 according to the output state of the comparator CMP. The tracking is adjusted automatically, as the input of is changed.

As described above, the tracking signal can be automatically adjusted by detecting the envelope signal of the video signal and applying it to the tracking mono-multi circuit of the servo controller by using the difference signal generated by comparing it with the tracking reference signal. There is an advantage that tracking can be performed precisely.

Claims (1)

An auto-tracking circuit of a VTR having an envelope detector which detects an envelope of a video signal and generates it as a DC voltage value, and a servo controller which inputs a predetermined control signal and performs tracking according to the signal. The comparator comprises a comparator for generating a difference signal by inputting a predetermined reference voltage for tracking as a comparator signal and a FET for generating the control signal linearly changed according to the output voltage of the comparator. Auto tracking circuit of the VTR, characterized in that it is operated to automatically adjust the tracking according to the envelope change.