KR900007909Y1 - Control circuit for speed of the head - Google Patents

Abstract

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Description

Mechanical position error correction circuit of head drum

1 is a detailed view showing an embodiment of a correction circuit of the present invention.

(A)-(i) of FIG. 2 is a waveform diagram of each part of FIG.

* Explanation of symbols for main parts of the drawings

1: rising point detection unit 2: falling point detection unit

3: 1st Government Administration 4: 2nd Government Administration

FF1, FF2: Flip-flop MM: Monomulti

HS: Head Switching Signal VS: Vertical Synchronization Signal

The present invention relates to a mechanical position error correction circuit of a head drum for correcting the mechanical position error of two video heads provided in a head drum in a video tape recorder.

In the cylindrical head drum, the two image heads are defined to be installed while maintaining an angle of 180 ° to each other. If the two video heads do not maintain an angle of 180 ° to each other and there is an error, the video head may not accurately track the recorded track of the video tape when the video tape is played. It can't be played back and many noise signals are mixed.

Therefore, the manufacturer of the head drum installed the two image heads at an angle of exactly 180 ° to each other using a microscope when fixing the image head to the head drum, but there was still an error in the installation position.

In order to correct such a mechanical position error, the time interval between the vertical synchronization signal of the reproduced video signal from the rising and falling time of the 30 kHz head switching signal for switching the video head is 6.5H (where H is the horizontal synchronization signal). It is fixed by adjusting with two variable resistors so that

However, correcting mechanical position errors with two variable resistors is not only very difficult and time consuming, but also requires considerable skill, and video tapes recorded on programs in video tape recorders with mechanical position errors in the red drum. When playing back there was a problem that can not be corrected.

In order to solve the above problems, the present invention devised a correction circuit for automatically correcting the mechanical position error of the head drum using a 30 kHz head switching signal and a vertical synchronizing signal. When described in detail as follows.

1 is a detailed view showing an embodiment of a correction circuit of the present invention, as shown therein, a capacitor C1, a resistor R1, and a diode D1, D2 for detecting a rising point of a head switching signal HS. Of the rising point detection unit 1 and the falling point of the resistor R2-R5, the transistor TR1, the capacitor C2, and the diodes D3 and D4 that detect the falling time of the head switching signal HS. A mono-multi (MM) triggered according to the output signals of the detector 2, the rising point detection unit 1 and the falling time detection unit 2 to generate a 6.5H wide reference pulse signal, and the rising point detection unit 1 A flip-flop (FF1) which is set according to the output signal of the < RTI ID = 0.0 >) < / RTI > It is set in accordance with the output signal of the viewpoint detector 2 and reset in accordance with the vertical synchronization signal VS, and the lower of the head switching signal HS is generated. A flip-flop FF2 that generates a pulse signal from the time point to the vertical synchronization signal VS and an output that generates a correction signal of the first image head based on a difference between the output signals of the flip-flop FF1 and the mono multi MM. The difference between the output signal of the flip-flop (FFF2) and the mono-multi (MM) and the first compensation (3) of the exclusive OA gate (XOR1), the operational amplifier (OP1) and the first electron volume (31) A second correction unit 4 composed of an exclusive orifice (XOR2), an operational amplifier (OP2), and a second electron volume 41, which generates a correction signal of the second image head, is constituted.

In the description of the drawings, reference numeral B ⁺ denotes an operating power source.

According to the present invention configured as described above, when the head switching signal HS of 30 입력 is input as shown in (a) of FIG. 2 while the operating power source B ⁺ is applied, the input head switching signal HS is raised. The differential point signal is differentiated through the capacitor C1 and the resistor R1 of the time detector 1 and the negative differential signal is removed by the diode D1, so that the rising point detector 1 has a head as shown in (b) of FIG. The differential signal is generated at each rising point of the switching signal HS.

In addition, the input head switching signal HS is inverted and amplified as shown in FIG. 2C through the resistors R2-R4 and the transistor TR1 of the falling-point detection unit 2, and the capacitor C2. And a differential through the resistor R5, and the negative differential signal is removed by the diode D3, so that the falling time detection unit 2 drops every time the head switching signal HS falls, as shown in (d) of FIG. A differential signal is generated.

In this way, the differential signal output from the rising time detector 1 and the falling time detector 2 is mixed as shown in (e) of FIG. 2 through the diodes D2 and D4 to trigger the monomulti (MM). Since it is applied to the terminal, the mono multi (MM) is triggered to output a pulse signal to the output terminal (OUT) as shown in FIG. Here, the values of the time constant circuits of the resistor R6 and the condenser C3 are set so that the monomulti MM outputs a pulse signal for 6.5 H from the rising time and the falling time of the head switching signal HS. The output pulse signal of MM) is used as a reference signal to correct the mechanical position error.

The output signal of the rising point detection unit 1 is applied to the set terminal SE1 of the flip-flop FF1, which is set therein, and the vertical synchronization signal of the reproduced video signal inputted as shown in (g) of FIG. Since the VS is applied to the reset terminal RE1 of the flip-flop FF1 and reset, the flip-flop FF1 is the output terminal Q1 as shown in (h) of FIG. 2 and the head switching signal HS. Pulse signal is output from the rising point of the signal to the vertical synchronization signal VS.

In addition, since the output signal of the falling-point detection unit 2 is applied to the set terminal SE2 of the flip-flop FF2, and it is set, the vertical synchronization signal VS is applied to the reset terminal RE2 and reset. The flop FF2 outputs a pulse signal to the output terminal Q2 from the falling time of the head switching signal HS to the vertical synchronizing signal VS as shown in (i) of FIG.

At this time, when the head drum has no mechanical position error or corrected so that there is no mechanical position error, the width of the pulse signal output from the flip-flops FF1 and FF2 becomes 6.5H, thereby outputting the mono-multi The signal is the same as the signal, and if there is a mechanical position error, it is larger or smaller than the width of the output signal of the mono multi (MM) in accordance with the positive and negative values of the mechanical position error.

As such, the pulse signals other than the outputs of the mono multi (MM) and the flip-flops (FF1) and (FF2) are exclusive oragate (XOR1) and (XOR2) of the first and second compensation parts 3 and 4. And the operational amplifiers (OP1) and (OP2) are input, so the exclusive OOR gates (XOR1) and (XOR2) output pulse signals during the time of mechanical position error, and the operational amplifiers (OP1) and (OP2) The first electronic volume 31 and the second electronic volume 41 are output by the direction signal of the positional error, and the exclusive oragate XOR1 is directed in the direction of the direction signal output from the operational amplifiers OP1 and OP2. , (XOR2) is adjusted during the time to output the pulse signal to output the correction signal to correct the mechanical position error.

That is, for example, when the width of the pulse signal output by the flip-flop FF1 is shorter than the width of the pulse signal output from the mono multi MM, the exclusive oragate during the difference time of the width of the pulse signal The XOR1 outputs a high potential and the operational amplifier OP1 outputs a positive potential to be input to the first electron volume 31, so the exclusive electronic question 31 XOR1 has a high potential. It is assumed that during the output time, the correction signal of the first image head is output while being adjusted in the positive direction, and the width of the pulse signal output by the flip-flop FF1 is longer than the width of the pulse signal output from the mono multi MM. In this case, the exclusive orifice XOR1 outputs a high potential for the difference time of the width of the pulse signal, and the operational amplifier OP1 outputs a negative potential so that the first electron volume 31 is the exclusive oragate XOR1. ) Outputs a pulse signal While adjusting in the negative direction, the correction signal of the first image head is output, and the second correction unit 4 also operates in the same manner as the first correction unit 3 to output the correction signal of the second image head. .

As described in detail above, the present invention automatically corrects a mechanical position error when there is a mechanical position error. Therefore, there is no need to perform the operation by correcting the mechanical position error. Even when playing a videotape recorded with a videotape recorder with a mechanical position error, the videohead has an effect of accurately tracking the recorded track of the videotape to watch a clean playback picture.

Claims (1)

A rising time detector 1 for detecting a rising time of the head switching signal HS, a falling time detecting part 2 for detecting a falling time of the head switching signal HS, and a rising time detecting part 1 and a falling time In accordance with the output signal of the detector 2, the mono-multi (MM) generates a reference pulse signal having a width of 6.5H from the time when the head switching signal (HS) rises and falls, and the output signal and the vertical of the rise time detector (1). The flip-flop FF1 which generates a pulse signal from the rising point of the head switching signal HS to the vertical synchronizing signal VS as the synchronizing signal VS, and the falling point detecting unit 2 and the vertical synchronizing signal VS. The first image is a difference between the flip-flop FF2 that generates a pulse signal from the falling point of the head switching signal HS to the resin air signal VS, and the output pulse signals of the flip-flop FF1 and the mono multi MM. First correction section 3 for generating a correction signal of the head, and output pulses of the flip-flops FF2 and mono-multi A second correction unit 4 to the head, characterized in that the drum configuration of mechanical position error correction circuit for generating a correction signal of the second video head drive arc.