KR900010455Y1 - Tracking auto-control device - Google Patents

Abstract

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Description

Tracking auto adjuster

1 is a conventional tracking device circuit diagram.

2 is a tracking device circuit diagram of the present invention.

3 is an explanatory diagram of a tracking adjustment operation.

4 is a waveform diagram of each part of the present invention.

* Explanation of symbols for main parts of the drawings

1: amplifier 2: frequency divider

3: phase-discrlminator 4: adder

5: amplifier 6: phase comparator

7: tracking mono multi 9: low pass filter (LPE)

10: peak-holder 11: the first buffer

12: comparator 13: second buffer

14: third buffer 15: fourth buffer

16: level-holder 17: flip-flop

V _D : Varactor diode

The present invention relates to a device for automatically adjusting the tracking of the video cassette recorder of the present invention, and particularly to a tracking automatic control device that can be easily applied to an existing tracking device and automatically adjusts the tracking adjustment to an optimum value. It is about.

In a video cassette recorder, during playback, the video head is reproduced by a different odometer and circuitry than when recording a video signal on the tape, so it is extremely difficult for the video head to accurately scan tracks recorded on the tape, and generally the original signal You will not be able to play 100%. Therefore, noise is generated on the screen, causing inconvenience to viewing, and various methods have been proposed to reduce such noise.

The most common method is a manual method of manually adjusting the tracking volume as shown in FIG.

In FIG. 1, when the capstan controlling the transfer of the tape is rotated, a pulse signal CFG is generated which is proportional to the speed. The pulse signal CFG is amplified by the amplifier 1 and then, at the frequency divider 2. It is divided at a constant rate and input to the phase discriminator 3.

The phase discriminator 3 applies the reference value and the error value corresponding to this difference to one input of the adder 4 according to the input divided signal value. At this time, the error value represents the current capstan rotation speed, that is, the speed difference value generated when the tape moving speed is compared with the reference value.

On the other hand, the control pulse (CTL) indicating the position where the video signal is recorded on the tape is reproduced and input at the Colthead, and the control pulse (CTL) is amplified by the amplifier (5) and then the one side input of the phase comparator (6). A constant voltage Vcc is applied to the input terminal of the tracking monomulti 7 according to time constants according to the values of the tracking volume VR, the resistor R, and the capacitor C. Is as shown in Fig. 3A, and when the potential of the input terminal A becomes constant, the value of the capacitor C is discharged at a time to form a sawtooth shape. Therefore, the waveform of FIG. 3A is input to the other input of the phase comparator 6. The phase comparator 6 generates a large wave as shown in FIG. 3 (b) from the moment when the output signal of the input tracking monomultiplex 7 becomes a low level as shown by t2 in FIG. As shown in (c) of the drawing, the sampled and hold level of the large wave at the rising edge of the input control pulse outputs an error value corresponding to a difference from the reference value. At this time, the error value indicates a phase error value that is different from the track originally recorded by the video head currently being scanned. The error value is transmitted to the capstan east part by applying an output signal added to the other input of the adder 4 to add the phase error and speed error. Allow the capstan to drive to compensate.

In this state, while the user looks at the screen, noise appears on the screen, and tracking is performed while moving the tracking adjustment volume VR little by little.

In other words, if the tracking volume VR is changed, the resistance value of VR + R is changed to change the charging time constant of the capacitor C, so that the output of the tracking monomulti 7 falls as shown by the dotted line in FIG. Time will change. Therefore, the rising point of the large wave in FIG. 3 (b) moves from t2 to the t1 side or the t3 side as shown by the dotted line, but since the control pulse does not change, the sampling of the large wave level at the rising point leads to the sampled large wave level. From Vs to Vs' or vice versa, the capstan phase error value, which differs from the reference value, changes. Therefore, the output signal of the adder 4 also changes, thereby slightly changing the phase of the capstan.

Therefore, the user adjusts the tracking by stopping the adjustment when the noise is minimized while looking at the screen.

Such a method has a problem that the user has to manually adjust while watching the screen, and also has a problem that the general user has difficulty in recognizing the noise minimum while directly looking at the screen.

In order to solve this problem, various automatic adjustment methods have been proposed. For example, the piezo-head is used to scan the track optimally as the head moves, but at high voltage and high cost. It is difficult to carry out such a problem, and it is not currently applied to VCRs.

Other digital gear elements have also been proposed, but this has not been applied because of the complexity of the circuit or other difficulties.

The present invention has been devised to solve all the problems of the manual method and the automatic adjustment method, excluding the manual method and providing the automatic tracking adjustment method for the convenience of the consumer, and applied to the home CR (VCR) as the automatic adjustment method. In addition to providing a simple circuit that is easy to record, it is also designed to be compatible with existing passive methods to facilitate implementation.

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

2 is a schematic diagram of a tracking device according to the present invention. When the reproduced video high frequency signal RF is applied as shown in the drawing, the high frequency signal RF is transmitted through the low pass filter 9 to the high frequency signal RF. After the envelope is detected, the peak level is detected by the peak holder 10 and applied to the first buffer 11, and the output signal level of the low pass filter 9 is directly applied to the second buffer 13. The output signal levels of the first and second buffers 11 and 13 are converted into appropriate levels by the third and fourth buffers 14 and 15 and applied to the level holder 16. The flip-flop 17 controls the level holder 16 according to the output signal state of the third buffer 14 to hold the output signal level of the fourth butter 15 at the level holder 10. and, the output signal of the level of the holder 16 is to convert the capacitance (capacitance) of baraek teodayi order (V _b) via a resistor (R ') of claim 1 is also tracking Is configured to control the output state of the multi-furnace (7).

That is, the entire circuit of FIG. 2 is configured to be connected to the input terminal of the tracking monomulti 7 instead of the cracking control unit 8 of FIG. 1 and is configured to be easily applied with compatibility to existing circuits. have.

Referring to the effect of the present invention configured in this way in detail as follows.

When the play key is first pressed while the tape is loaded, playback starts. The video head randomly scans the track until the servo system locks after loading. The tooth is reproduced at least once more as shown in FIG. At this time, the reproduction high frequency signal RF is detected by an envelope through the low pass filter 9, and the peak value of the envelope is held in the peak holder 10, and then the first buffer 11 is shown in FIG. Once the servo system is locked, the high frequency signal RF currently being reproduced as shown in (b) of FIG. 4 is detected in the second buffer 13 after the envelope is detected through the low pass filter 9. It is applied as shown in (b ') of FIG.

As such, the signals applied to and output from the first and second buffers 13 are compared in the comparator 14 as shown in FIG. 4C, and the secondary signals are output, and the secondary signals are output from the third buffer. As shown in (C ') of FIG. 4 at (14), it is converted to an appropriate level and applied to the flip-flop 17, and simultaneously applied to the level holder 16 via the fourth buffer 15 again.

Accordingly, the level holder 16 supplies the current voltage level to the varactor diode V _D , and the varactor diode V _D changes its capacitance according to the applied voltage.

By the way, the varactor diode (V _D ) at the initial charge level is almost started at "0" (Zero), so that the charging potential rises to a certain level, that is, the time from the third degree to the falling of the sawtooth wave elapses, As the charge level of the varactor diode (V _D ) gradually increases, the time to rise to a constant potential decreases, so the sawtooth drop point in FIG. 3 is gradually moved from t13 to t1.

This operation has the same result as changing the tracking volume VR in FIG. 1 to change the charging time of the capacitor C, that is, the falling point of the tracking monomulti 7.

Therefore, the tracking adjustment is automatically performed. When the signal level reproduced at a certain point almost coincides with the peak value, the output level of the comparator 12 is low and the output level of the third buffer 14 is also low.

At this time, the fourth buffer 15 properly converts the low signal level of the third buffer and applies the varactor diode V _D through the level holder 16 to set the period of the tracking monomulti 7 to a corresponding value. In this case, the flip-flop 17 recognizes the output signal of the third buffer 14 as a low level and outputs a hold control signal to the level holder 16 to control the current optimum state.

That is, when the hold control signal is applied from the flip-flop 17, the level holder 16 ignores the application signal of the fourth buffer 15 and the current held level, that is, the varactor diode V _{D which} is the most optimal tracking. Since the applied voltage of N) is maintained, the period of the tracking monomulti 7 is kept constant so that the capstan control signal is kept as it is now. However, if the tracking is shifted due to other conditions, the current playback signal level of the first buffer 13 is decreased, and the output of the comparator 12 is increased. The automatic tracking adjustment is performed again, and when the low point is output from the third buffer 14, the hold control signal is output again.

As such, the present invention adjusts the tracking automatically and automatically locks at the optimum state, thereby eliminating the inconvenience of the user manually adjusting the tracking, for convenience, and also by adjusting the conventional tracking state automatically and accurately by adjusting the conventional user's adjustment. In addition to eliminating the inaccuracies of the present invention, it is compatible with existing tracking devices, and the simple construction makes it easy to implement in home video cassette recorders.

Claims (1)

A tracking control device which performs tracking adjustment by comparing the output signal phase of the tracking monomulti 7 with the phase of the control pulse CTL through the amplifier 5 and the phase comparator 6, wherein the high frequency signal RF to be reproduced. A low pass filter 9 for detecting the envelope, a peak holder 10 for detecting and holding a peak value in the output signal of the low pass filter 9, and an output signal of the peak holder 10 are converted to an appropriate level. The first buffer 11, the second buffer 13 for converting the output signal of the low pass filter 9 to the appropriate level, and the output signals of the first, second buffers 11, 13 The comparator 12 for outputting the difference signal by comparing the, the third, fourth buffer 14, 15 for sequentially converting the output signal of the comparator 12 to the appropriate level, and the third buffer 14 ) Is a Philip flop 17 for outputting a hold control signal when the output signal level is below a predetermined level, and the hold control signal is output from the flip flop 17. When not varactor diode (V _D) and is the varactor diode (V _D), when applied to keep the input side of the tracking mono-multi 7 and the hold control signal is output to the output signal of the fourth buffer 15 And a level holder (16) for maintaining a current level applied to the input side of said tracking monomulti (7).