KR910001298Y1 - Noise position fixing circuit in case of high speed reproduction for automatic track finding method - Google Patents

Abstract

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Description

Noise position fixing circuit for high speed playback with automatic trackfinding

1 is a trajectory diagram of a video head during high speed playback in a general VTR.

2 is a trajectory diagram of a video head during high speed playback in a VTR of the present invention.

3 is a state diagram of an output capable of fixing a noise bar during high-speed playback of a VTR.

4 is a circuit diagram of the present invention.

5 is a waveform diagram of each part of the present invention circuit diagram.

6a to (e) are detailed implementation circuit diagrams of the inventive circuit diagram.

* Explanation of symbols for main parts of the drawings

1: pulse generator 2: delay generator

3,8 divider 4: square wave generator

5,6: Differentiator 7: JK-Flip-flop

9: ATF reference signal generator 10: ATF control circuit

11: drive circuit DM: drum motor

AD: Andgate CM: Canston Motors

EX: Exclusive Oagate

The present invention is a high-speed playback of the automatic track-finding method in which a white horizontal noise bar can be fixed during a high-speed playback in a video tape recorder (VTR) employing the automatic track-finding (ATF) method. Time noise position fixing circuit.

In the 8mm video tape recorder, the automatic track-finding method is mainly used for phase control of the capstan motor. The automatic track-finding method uses the ATF reference signal (f ₁ -f ₄ ) as a relatively low frequency band of 100-500KHZ. The video track is mixed with the luminance signal, the color signal, and the audio signal, and is sequentially recorded on the video track, and the video track can be identified using the ATF reference signals f ₁ -f ₄ during playback. When the ATF reference signals f ₁ , f ₂ , f ₃ , and f ₄ are recorded, if the ATF reference signals f ₃ , f ₂ , f ₄ , and f ₁ of the playback block are supplied during playback, the trajectory of the video head is The rotational phase of the capstan motor is controlled so that f ₁ → f ₂ → f ₃ → f ₄ .

When you perform a PICTURE SEARCH mode where you can quickly find a desired screen by playing the screen at high speed on a VTR that employs this automatic track-finding method, noise bars appear and these noise bars move up and down or continue in one direction. It was not able to reproduce good images.

The present invention is to provide a noise position fixing circuit that can expect a good image in the high speed playback mode by fixing the lateral noise bars generated during the high speed playback mode in consideration of such a point. same.

First, the cause of the noise bar in the high speed playback mode (picture search mode) will be described with reference to FIG. 1.

The video head traces the video track laterally to trace N pulses at a field time (where N is the capstan speed in the high-speed playback mode) at an angle. Written by The tracks of the traces are traced, and the detected signal forces are weak, causing noise bars to appear.

In other words, FIG. 1 shows the video red trajectory on the video track in the 9x picture search mode, and when the AZIMUTH angle of the field is recorded, four fields (headed portions) having different head azimuth angles appear. As described above, in a field having a different AZIMUTH angle, the noise signal is higher than that of a video signal, thereby preventing a clear screen.

Also it appears noise bars may of (NOISE BAR) CH ₁ head bar 3 as noise are four if the trace from beginning to end of track from CH ₂ CH ₂ tracks.

As such, the number of noises may vary depending on the timing when the head enters the track in the picture search mode. Also, if the rotation speed of the capstan motor is not uniform, the noise bars are shaken up and down. To avoid this, first, the track entry timing of the video heads must be appropriate (enter the tracks of the same azimuth angle), and second, a condition must be established that the tape advancing speed must be constant.

The first condition here is that when the capstan motor stops and starts to rotate, the initial head of the video head must be a different azimuth track, and the rotation speed of the capstan motor must be an odd multiple of the normal rotation speed.

And the subject innovation is the CH ₁ head for fixing to the noise bar out of three in the case that the number to satisfy the condition as described above in the 29-speed picture books worth Modal as to help start the trace in CH ₂ tracks CH ₂ To end the trace in field 1.

That is, as shown in FIG. 2, the video head has the ATF reference signal component f ₄ → f ₁ → f ₄ → f ₃ . When tracing one field of f ₄ , the ATF reference signal is the same as in normal playback. f ₂ → f ₁ → f ₄ → f ₃ . must be in the order of f ₂ .

As shown in FIG. 2, reference selection signals 1 and 2 as shown in FIG. 3 are applied to the ATF reference signal generator 9 of FIG. 4 so that the trajectory of the head can be controlled even when the capstan motor is rotated at high speed in the picture search mode as shown in FIG. 2. When the supplied ATF reference signal as shown in FIG. 3 is outputted, the noise bar is fixed. In order to generate the reference signals 1 and 2 and output the ATF reference signal, FIG.

FIG. 4 is a circuit diagram of the present invention, and the sine wave signal detected at the head of the drum motor DM is connected to the retarder 2 and the divider 3 connected to the variable resistor VR ₁ for phase adjustment through the pulse generator 1. After configured to be applied to the output of the retarder (2) is output through the square wave generator (4) to the head switching pulse (HP), the output pulse of the directional wave generator (4) to the differentiator (6) At the same time, the inverter is inverted by the inverter I ₁ to be applied to the differentiator 5, and the output of the differentiator 5 and 6 is applied to the input terminal J of the JK flip-flop 7. On the other hand, the output of the differentiator 5 and 6 and the output of the divider 3 are logically multiplied by the AND gate AD so as to be applied to the clock terminal CK of the JK flip-flop 7.

The output terminal Q of the JK-flip-flop 7 is applied to the ATF reference signal generator 9 as the reference signal 1, and is applied to one terminal of the exclusive ore gate EX. After the RPS signal (reverse fast regeneration: REVERSE PICTURE SEARCH) generated by the scissor micom is applied to the other terminal of the gate EX, the output of the exclusive oar gate EX is applied to the divider 8. The output of the divider 8 is configured to be applied to the ATF reference signal generator 9 as the reference signal 2.

The output of the ATF reference signal generator 9 is supplied to the ATF control circuit 10 to control the capstan motor CM through the drive circuit 11.

The fifth turn and also each part of the subject innovation waveform diagram, as an exemplary detailed circuit diagram of the present invented circuit turns claim 6 (a) turning OP is connected to the resistance (R ₁ -R ₇₎ that shows a fourth-degree pulse generator (I) The amplifier OP ₁ and OP ₂ are configured in two stages so that the sinusoidal input signal Vi is output as a square wave output signal Vo. FIG. 2b shows the delay unit 2 of FIG. The input terminal Vi of the IC ₁ is configured such that an output through a DC blocking capacitor C ₁ and a resistor R ₈ is applied, and then an output terminal (C ₂ ) and a variable resistor VR ₁ are applied. Vo) is configured to determine the delay time. And (c) shows the differentiator (5) and (6) of FIG. 4, which constitutes a circuit using charge / discharge time composed of a capacitor (C ₃ ) and a resistor (R ₇ ), and the high voltage prevention diode (D ₁ ) (D) shows the divider (3) and (8) of FIG. 4, and is composed of D-flip flop (FF ₁ ), and (e) shows the ATF reference signal (9) of FIG. In response to the logic signal of the reference signal 1 and the logic signal of the reference signal 2 with the division ratio up to the divider 4, the signal having one of four frequencies according to the input signal It is configured to select from the gates A ₁ -A ₄ and output through the ora gate OR ₂ .

The present invention configured as described above will be described in detail with reference to the circuit diagram of FIG. 4 and the waveform diagram of FIG. 5.

The sinusoidal signal as shown in FIG. 5a detected at the head of the drum motor DM is applied to the pulse generator 1, and the pulse generator 1 receives the sinusoidal signal as shown in FIG. 5c which is the meaning of the phase signal. A PG (PHASE GENERATOR) signal is generated and applied to the delay unit 2, while a FG (FREQUENCY GENERATOR) signal is generated and applied to the frequency divider 3 as shown in FIG.

In the retarder 2, the variable resistor VR ₁ is appropriately varied to delay the PG signal and then applied to the square wave generator 4 in order to obtain the head switching pulse HP according to the phase of the video head.

The square wave generator 4 receives the output of the retarder 2 and generates a head switching pulse HP as shown in FIG. 5E and the head switching pulse HP is shown in FIG. The derivative is applied to the input terminal K of the JK flip-flop 7 while the head switching pulse HP is inverted at the inverter I ₁ and then differentiated as shown in FIG. 5f at the differentiator 5. It is applied to the input terminal J of the JK flip-flop 7.

On the other hand, the divider 3 divides the FG signal as shown in FIG. 5B and outputs the pulse as shown in FIG. 5D, and the output pulse of the divider 3 is different from the differential signal of the differentiator 5 and 6. After being multiplied by AND at the AND gate AD, it is applied to the clock terminal CK of the JK flip-flop 7.

Therefore, in the JK flip-flop 7, when the output of the AND gate AD falls from the high level to the low level, the JK depends on the output state of the differentiator 5 (6) (that is, the output state of the head switching pulse HP). The output terminal Q of the flip-flop 7 is outputted differently as in FIG. 5h.

That is, the reference signal 1 output from the output terminal Q of the JK flip-flop 7 has a different output when the head switching pulse HP is at a high level and at a low level.

At this time, the reference signal 1 output from the JK flip-flop 7 is applied to the ATF reference signal generator 9.

The reference signal 1 output from the JK-flip-flop 7 is divided by the divider 8 to obtain the reference signal 2. Is the level change of the reference signal 2 made at the falling edge of the reference signal 1? The order of the reference signals varies depending on whether the rising edge is at the rising edge. The order of the reference signals is different in the case of FORWARD PICTURE SEARCH and REVERSE PICTURE SEARCH.

That is, the reference signal 1 output from the output terminal Q of the JK flip-flop 7 is applied to one terminal of the exclusive orifice EX, and the reverse high speed reproduction is performed to the other terminal of the exclusive orifice EX. When the RPS signal applied at the high level is applied, in the case of REVERSE PICTURE SEARCH, the reference signal 1 is inverted and supplied to the divider 8 so that the level change of the reference signal 2 at the rising edge of the reference signal 1 is applied. Occurs and in the case of forward fast playback (FORWARD PICTURE SEARCH), the level change is made at the falling edge.

Therefore, the divider 8 generates the reference signal 2 as shown in FIG. 5i and applies it to the ATF reference signal generator 9, and the ATF reference signal generator 9 generates the ATF reference signal to generate the ATF control circuit 10. In the ATF control circuit 10, when the ATF reference signal is selected and input according to the state of the reference signal 1 and the reference signal 2, the order of the ATF reference signal is f ₄ , f ₃ , f during the forward rotation playback mode. ₂ , f ₁ . Must be in order and in reverse play mode f ₂ , f ₃ , f ₄ , f ₁ . In order, the ATF reference signal generation of the ATF reference signal generator 9 becomes as follows according to the input.

The output of the ATF control circuit 10 controls the driving of the capstan motor CM through the drive circuit 11.

As a result, the present invention supplies the reference signals 1 and 2 to the ATF reference signal generator as described above, obtains the ATF reference signals in a certain order, and supplies them to the ATF control circuit, thereby minimizing noise bars and eliminating shaking during high speed playback. It is.

Claims (1)

A pulse generator 1 receiving the signal detected by the head of the drum motor DM to generate an FG signal and a PG signal, a divider 3 for dividing the FG signal of the pulse generator 1, and the pulse A delay unit 2 for delaying the PG signal of the generator 1 for a predetermined time, a square wave generator 4 for generating a head switching pulse HP in response to the delay signal of the delay unit 2, and the square wave The head switching pulse HP of the generator 4 is differentiated and the head switching pulse HP inverted by the inverter I ₁ is differentiated and applied to the input terminal J (K) of the JK flip-flop 7. The AND gate which applies the clock terminal CK of the JK-flip-flop 7 by logically multiplying the differentiator 5, 6, the output of the differentiator 5, 6, and the output of the divider 3. (AD), an exclusive oragate (EX) for causing the output of the JK-flip-flop 7 to be reverse or fast reverse playback (RPS) and an exclusive oragate; An ATF reference signal generator for generating an ATF reference signal using the divider 8 for dividing the output of the passive oar gate EX and the outputs of the divider 8 and the JK flip-flop 7 as reference signals. (9) and an ATF control circuit (10) for receiving the ATF reference signal of the ATF reference signal generator (9) and controlling the capstan motor (CM) through the drive circuit (11). Noise position fixing circuit at high speed playback.