KR940004492B1 - Vertical vibrating-proof system and control method thereof - Google Patents

Abstract

The system for obtaining optimal image by sensing the synchronous signal and varying the tracking data when changing the speed includes a synchronous signal sensor (10), a microprocessor (30) sensing the composite synchronous signal from the sensor and a brightness/colour signal processor (20) and checking the vertical synchronous signal, and a servo system (40) sensing the control signal from the tape and controlling the phase according the data preset by the microprocessor.

Description

Screen shake prevention system and control method

1A to 1D are conventional waveform diagrams of respective signals.

2 is a signal waveform diagram of a conventional special playback.

3 is a block diagram of a vertical anti-shake system of the present invention screen.

4A to 4C are waveform diagrams of respective parts different from those in FIG.

5 is a vertical anti-shake control flow chart of the screen of the present invention.

6A to 6C are signal waveform diagrams according to phase control.

7 is a signal waveform diagram during special reproduction according to the present invention.

* Explanation of symbols for main parts of the drawings

10: synchronization signal detection unit 20: luminance / color signal processing unit

30: microcomputer 40: servo system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a playback screen of a VCR, and in particular, a video high frequency level of a video signal read from a video head in order to prevent the screen from vertically floating during cue or review, which is a special playback. The present invention relates to a vertical anti-shake system of a screen which changes tracking data through servo control to maintain an optimal screen, and a control method thereof.

Conventionally, a composite video signal as shown in FIG. 1a of a recorded tape is read out, and a composite sync (C.SYNC) signal as shown in FIG. 1b is separated from the signal and applied to the servo system, and the composite composite signal (C) is separated. .SYNC) After reading the signal, it configures the ROM data in the servo system to output a DV SYNC signal such as the 1c degree, which is delayed by several hundred μsec based on the composite sync signal, to the luminance / color processing unit. When the deteriorated part is low as in Fig. 1d at the time, it may not be able to detect synchronously. Therefore, the servo system receives the composite sync (C.SYNC) signal separated by the color / luminance signal processor from the servo system and then uses it as a reference signal. Grab the vertical sync part to output from the servo system to the forced sync port of the luminance / color signal processor. To detect and to prevent errors.

However, in such a conventional circuit, if the DVSYNC signal fails to cover when the high frequency level is deteriorated before or after the forced synchronization portion, the various TVs may change to each AFC characteristic. There are many types of TVs, TVs that don't tremble, which can't be handled perfectly with forced vertical synchronization alone.

Also, when the flyback high frequency (PB-RF) waveform read from the video head from the tape of the X2 double speed pattern trajectory as shown in Fig. 2a deteriorates as in the "E" region shown in Fig. 2c, a noise bar appears on the screen. If the head switching signal is deteriorated in the RF waveform at the negative falling edge as shown in Fig. 2b, it is outputted as composite video, so noise is introduced into the vertical synchronization area, and the vertical synchronization of the TV becomes unstable. Vertical tremors occur.

In view of such a conventional deficiency, the present invention has devised a system for preventing vertical shake of a screen and a method of controlling the same to obtain an optimized surface by detecting a SYNC signal and changing tracking data when shifting. Referring to the drawings in detail as follows.

3 is a block diagram of the vertical anti-shake system of the present invention, and the composite synchronization (C.SYNC) is detected by the synchronization signal detection unit 10 for detecting a synchronization signal, and the synchronization signal detection unit 10 and the luminance / color signal processing unit 20. ) And a servo system 40 which detects a control signal CTL from a tape and controls phase according to a preset data value of the microcomputer 30.

Referring to the operation, effects of the present invention configured as described above in detail.

First, a control method for obtaining an optimal screen with tracking data in the microcomputer 30 will be described with reference to FIG. 5.

In the shift mode, when the tracking data (initial value) corresponding to the shift is output to the servo system 40, the servo capstan phase control is performed according to the data, and if the count is normal, the tracking data value is fixed. If it is abnormal, the tracking is changed to N steps. The resolution is determined in this circuit as it depends on how many steps the video head switching interval, i.e., one frame, is divided in the microcomputer 30.

After changing the tracking to N step, M value is increased by 1, where M value is to know how many loops of N step changes are made when abnormal vertical synchronization (H.SYNC) is entered. If the microcomputer 30 keeps checking for abnormal vertical synchronization (H.SYNC) because it is a tape or a heavily used tape, the tracking may change frequently and the screen may not lock. To fix it to a value.

If M is not x value, check H.SYNC again and if the number of vertical synchronization is normal, it is fixed to the changed tracking data value and becomes the best screen.

In the above description of the servo capstan phase control, the capstan reference counter in the servo system 40 is synchronized with the vertical synchronization signal in the EE mode, and the color carrier frequency (NTSC is 3.58 MHz and PAL is 4.43 MHz) is constant. As a constant ring counter that circulates through the count, the EE mode is a video signal mode other than the playback mode.

In the counter as described above, the preset value as shown in FIG. 6a is triggered by the preset data designated by the microcomputer 30 to count the capstan trapezoidal waveform as shown in FIG. 6b. The flyback control signal as shown in FIG. Digital phase control is performed so as to be at the center value of the inclined portion.

If it is not optimal in FIG. 7, the preset data of the microcomputer 30 is inputted from the servo system 40, and the flyback control (PB, CTL) is adjusted as shown in FIG.

In FIG. 3, the reason why the microcom 30 receives the composite sync (C.SYNC) signal as shown in FIG. 4c output from the luminance / color signal processor 20 is that the composite sync (C.SYNC) signal is synchronized with the sync signal. If it is received from the detection unit 10, according to the detection point of the synchronization signal detection unit 10, that is, if the detection unit 10 is very strong against noise, even if the noise is determined to be normal, the TV screen may actually shake. Therefore, the composite synchronizing (C.SYNC) signal, which has passed through the luminance / color signal processing unit 20, is input to the microcomputer 30 by ringing the servo system 40.

In addition, when the synchronization signal is detected by the synchronization signal detection unit 10, the synchronization detection signal "H" is output to the microcomputer 30, which is to prevent the operation as described above when the signal does not carry the signal on the tape. .

As described above, the synchronization signal is checked by the microcomputer 30 from the synchronization signal detection unit 10 and the luminance / color signal processing unit 20, and the tracking changed by the servo system 40 when the screen is not optimal. By outputting the data, the flyback high frequency waveform is prevented from deteriorating at the video synchronizing region to achieve the optimum screen.

As described in detail above, the present invention checks a composite sync (C.SYNC) signal output from the sync signal detector and the luminance / color signal processor, and applies the preset data to the servo system. By detecting the phase of the control signal from the tape and controlling the phase, it is possible to view an optimal screen without shaking in the shift mode.

Claims (2)

A synchronous signal detector 10 for detecting a synchronous signal and a microcomb 30 for detecting vertical synchronous (C.SYNC) signals of the synchronous signal detector 10 and the luminance / color signal processor 20 to check vertical synchronization. And a servo system (40) for detecting a control signal (CTL) from a tape and controlling the phase according to a preset data value of the microcomputer (30). In the shift mode, when the microcomputer 30 applies tracking data (initial value) corresponding to the shift mode to the servo system 40, the control signal CTL is detected from the tape according to the tracking data value, and phase control is performed. 30. The vertical sync is counted from the composite sync (C.SYNC) signal applied to 30), and if it is normal, it is fixed to the tracking data value. If abnormal, the tracking data is changed to N steps to increase the M value by 1 to a predetermined value (x). A method for preventing vertical shake of a screen, characterized in that the circuit is fixed to the first tracking data value.