KR0151277B1 - Control circuit of head drum relative speed and the method thereof - Google Patents

Abstract

The present invention relates to a video head drum relative speed control circuit and method for reducing friction between a video head and a tape in FF / REW mode to improve head wear and tape wear.

The present invention provides a regeneration control pulse detection unit for detecting regeneration control pulses generated when the head drum rotates in the FF / REW mode, a pulse counting unit for counting regeneration control pulses detected by the regeneration control pulse detection unit, and the pulse counting unit. The tape speed detector detects the feed distance of the current tape by multiplying the counted value by the interval between control pulses according to the playback mode of the current tape, and the feed distance of the current tape detected by the tape speed detector is determined by the diameter of the head drum. The drum speed control unit is configured to calculate the target rotational speed of the head drum by dividing by the circumference and to control the head servo to rotate the head drum at the calculated target rotational speed to improve tape wear and head wear in the FF / REW mode. Prolong the life of the tape and reduce head and deck Prevent contamination

Description

Video head drum relative speed control circuit and its method

1 is a block diagram of a conventional video head drum speed control circuit.

2 is a block diagram of a video head drum relative speed control circuit according to the present invention.

3 is a flowchart illustrating a video head drum relative speed adjusting method according to the present invention.

* Explanation of symbols for main parts of the drawings

10 head drum 20 drum frequency generator

30: drum phase generator 40: servo circuit

41: speed control section 42: phase control section

43: amplification unit 50: regeneration control pulse detection unit

60: pulse counting unit 70: tape speed detecting unit

80: drum speed control unit

The present invention relates to video head drum speed control in a video cassette recorder (hereinafter referred to as VCR), and more particularly to fast forward (hereinafter referred to as FF) and fast rewind ( Rewind (hereinafter referred to as REW) mode relates to a video head drum relative speed control circuit and method for reducing head friction and tape wear by reducing friction between the video head and the tape.

In general, in the recording mode of the VCR, the drum servo controls the rotational phase of the drum motor to always rotate in synchronization with the phase of the normal video signal recorded so that the vertical synchronizing signal in the video signal is recorded together at a predetermined position on the tape. In the regeneration mode, the drum servo controls the rotation speed of the motor in the drum motor so that a regeneration signal without time axis fluctuation is obtained.

FIG. 1 is a block diagram showing such a conventional video head drum speed control circuit, and includes a drum frequency generator (hereinafter referred to as DFG) 20 to detect rotation of the video head drum 10. A drum phase generator (hereinafter referred to as DPG) 30 is designed.

At this time, the DFG 20 is a coil designed at a predetermined angle on the drum circumference to obtain a sine wave of 24 cycles per revolution of the drum, and the DPG 30 is a sensor coil designed as one at a predetermined position on the drum circumference. One cycle of pulse waveform is obtained.

In addition, the speed controller 41 of the servo circuit 40 uses the video head drum according to the mode designation signal output from the system control microcomputer (not shown) based on the FG signal generated by the DFG 20. The rotational speed of 10) is detected and output to the non-inverting end (+) of the amplifier 43.

In addition, the phase controller 42 of the servo circuit 40 detects the rotational phase of the video head drum 10 according to the mode designation signal on the basis of the PG signal generated by the DPG 30. Output to the inverting end (-) of (43).

The amplifier 43 amplifies the speed and phase data detected by the speed controller 41 and the phase controller 42 to a logic level to control the speed and phase of the head drum 10.

At this time, in the FF / REW mode, the servo circuit 40 controls the speed constantly in a state in which the rotation speed of the head drum 10 is fixed with respect to the normal regeneration mode, so that there is almost no change in speed as compared with normal regeneration.

That is, the tape proceeds with a travel path, and the head drum 10 at this time rotates with a rotational speed of about 5.8 m / sec for NTSC and 4.8 m / sec for PAL.

On the other hand, the video tape proceeds at a maximum of 2 m / sec for FF and REW.

Therefore, in the FF mode, the video head and the video tape are rubbed with the rotation speed of the head drum 10 and the relative speed deviation of about 3.8 m / sec (= 5.8 m / sec-2 m / sec), and in the REW mode. The video head and the video tape rub with a relative speed deviation of about 7.8 m / sec (= 5.8 m / sec-(-2 m / sec)).

Therefore, the relative speed deviation becomes friction immediately, and as the relative speed deviation increases, the video head and the video tape wear out, and the worn surface acts as a foreign material to the video head and the deck odometer, resulting in a decrease in reliability. In addition, the tape transfer motor acts as a load, causing power loss and limiting of operation.

In other words, in the FF / REW mode, since the relative speed deviation of 10 times or more occurs than normal playback, the deviation of the video head drum speed and the tape feeding speed becomes too large, resulting in tape damage and head wear as well as video head. According to the repeated scan of the whole part, the surrounding dust or foreign matter fills the video head gap of about 0.3μm, which causes the headlessness.

The present invention is to solve the above problems, an object of the present invention is to reduce the friction between the video head and the tape in the FF / REW mode video head drum relative speed control to solve the head wear and tape damage and head debris In providing a circuit.

Another object of the present invention is to calculate the traveling distance per unit of the current tape by counting the regeneration control pulse during the rotation of the drum motor in the FF / REW mode, and then divided by the diameter and the circumference of the rotating video head drum, the speed of the current tape By matching the speed between the rotating head and the rotating head, the video head drum relative speed is controlled to improve tape wear and head wear to prolong the life of the head and tape and to prevent contamination of the head and deck by dust of worn tape. In providing a method.

A feature of the present invention for achieving the above object is that the DFG and the circumference of the head drum are designed in advance at a predetermined angle on the circumference of the video head drum to generate a sine wave of a predetermined cycle during one rotation of the head drum. DPG, which is designed at the determined position and outputs one cycle of pulse waveform in one rotation of the head drum, and controls the speed and phase of the head drum according to the FG signal, PG signal, and mode designating signal generated from the DFG and DPG. A video head drum speed control circuit composed of a servo circuit, comprising: regeneration control pulse detection means for detecting a regeneration control pulse generated when the head drum is rotated in an FF / REW mode, and detected by the regeneration control pulse detection means; Pulse counting means for counting a reproduction control pulse, and the value counted by the pulse counting means and the playback mode of the current tape. A tape speed detecting means for detecting the feed distance of the current tape by multiplying the interval between control pulses, and dividing the feed distance of the current tape detected by the tape speed detecting means by the diameter and the circumference of the head drum to determine the target rotational speed of the head drum. Calculating and controlling the servo circuit to rotate the head drum at the calculated target rotational speed.

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

2 is a block diagram showing a video head drum relative speed control circuit according to the present invention.

Referring to FIG. 2, a coil is designed at a predetermined angle on the circumference of the video head drum 10 to generate a sine wave of a predetermined cycle in one rotation of the head drum 10, and the head drum 10. DPG (30), the DFG (20), DPG (30) for designing one coil at a predetermined circumferential position of the circumference and outputting a pulse waveform of one cycle during one rotation of the head drum (10). It consists of a servo circuit 40 for controlling the speed and phase of the head drum 10 by the FG signal and the PG signal generated by the.

At this time, the servo circuit 40 detects the speed of the head drum 10 on the basis of the FG signal generated by the DFG 20 and applies the mode designation signal input from a system control microcomputer (not shown). Therefore, the speed controller 41 for controlling the rotational speed of the head drum 10 and the phase of the head drum 10 are detected on the basis of the PG signal generated by the DPG 30 and input from the system control microcomputer. The phase controller 42 for controlling the phase of the head drum 10 in accordance with the mode designation signal, and the output of the speed controller 41 and the phase controller 42 are amplified to a logic level, It consists of an amplifier 43 that controls speed and phase.

In addition, a regeneration control pulse detection unit 50 for detecting regeneration control pulses generated when the head drum 10 rotates in the FF / REW mode, and a regeneration control pulse detected by the regeneration control pulse detection unit 50 for the second time. A pulse speed detection unit 70 for counting by a unit, a tape speed detection unit 70 for detecting a current tape speed by multiplying the value counted by the pulse count unit 60 with a reference control pulse, and the tape speed detection unit And a drum speed controller 80 which controls the servo circuit 40 according to the speed of the current tape detected at 70 so that the relative speed of the video head and the video tape becomes '0'.

3 is a flowchart for performing a video head drum relative speed adjusting method according to the present invention.

According to the present invention configured as described above, a sine wave of a predetermined cycle is generated in the DFG 20 during one rotation of the head drum 10, and a pulse waveform of one cycle is output from the DPG 30.

At this time, the speed controller 41 of the servo circuit 40 detects the speed of the head drum 40 based on the FG signal generated by the DFG 20 and outputs it from a system control microcomputer (not shown). The signal for controlling the rotational speed of the head drum 10 is output to the non-inverting end (+) of the amplifier 43 according to the mode designation signal.

In addition, the phase controller 42 of the servo circuit 40 detects the phase of the head drum 10 based on the PG signal generated by the DPG 30, and then the head drum 10 according to the mode designation signal. The control signal for controlling the rotational phase of the output to the inverting end (-) of the amplifier 43.

Therefore, the amplifier 43 amplifies the speed and phase data detected by the speed controller 41 and the phase controller 42 to a logic level to control the speed and phase of the head drum 10.

At this time, when the mode designating signal input from the system control microcomputer is the FF or REW mode, the regeneration control pulse detector 50 detects the regeneration control pulse generated when the head drum 10 rotates. The following operation will be described with reference to FIG.

That is, in the FF mode (step 301), the rotation direction of the head drum 10 is designated as the forward rotation direction (step 302). If the FF mode is not the FF mode in the step 301, the rotation of the head drum 10 is performed. The direction is designated as the reverse rotation direction (step 303).

Then, FF or REW is carried out in the loading state while the head drum 10 is rotated forward or backward at a predetermined target rotational speed (step 304).

Then, the regeneration control pulse generated at this time is detected by the regeneration control pulse detection unit 50 and input to the pulse count unit 60, and the pulse count unit 60 counts the regeneration control pulse in seconds and sets the variable A. (Step 305).

At this time, the tape speed detection unit 70 calculates the feed distance per unit second of the current tape by multiplying the A variable in step 305 by the interval between the reference control pulses according to the playback mode of the tape (step 306). Here, the transfer distance per unit second of the current tape is set as a variable B.

Then, the target rotational speed of the video head drum 10 is calculated by dividing the B variable, which is the feeding distance per second of the current tape, calculated in the step 306 by the diameter of the rotating video head drum 10 and the circumferential ratio 62π. (Step 307). Here, the target rotational speed of the head drum 10 calculated in the step 307 is set to a variable C.

At this time, the drum speed control unit 80 controls the speed control unit 41 and the phase control unit 42 of the servo circuit 40 to rotate the head drum 10 at the target rotational speed calculated in the step 307. The speed of the advancing tape and the speed between the rotating heads coincide (step 308).

Therefore, the relative speed between the video head and the video tape becomes '0'.

At this time, if the stop mode is specified from the system control microcomputer, the program is ended, and if not specified, the program returns to the step 305 and counts the reproduction control pulse in seconds, and then proceeds to the subsequent process ( Step 308).

For example, when the tape speed is FF at 60 times the NTSC SP mode, the number of control pulses counted by the pulse counting unit 50 appears from 30 / sec to 1800 / sec (A variable) during normal playback. Assuming that, the distance between one control is 33.34 mm / sec / 1 / 29.94 = 1.11 mm and the traveling speed is 1800 x 1.11 mm = 1998 mm (variable B).

That is, since the absolute velocity of the tape is 1998 mm / sec, the relative speed that minimizes the friction between the video head drum and the tape is the rotation speed of the video head drum at 1998 mm / sec, so n ≒ 10.26 rps at 1998 mm = 62πn. Becomes

Therefore, if the rotational speed of the head drum 10 is set to 10.26 rps (C variable), since the speed of the tape currently in progress coincides with the speed of the rotating head, the relative speed of the video head and the tape becomes '0'.

On the other hand, in the REW mode, the rotational direction of the drum and the conveying direction of the tape are reversed in the related art, and thus the relative speed between the two objects is represented by the sum of the traveling speeds of the two objects, which is more adverse condition. And minimize the friction between the two objects by performing the same calibration as in the FF mode.

On the other hand, the tape without the control pulse is corrected in advance by the drum speed based on the tape speed that the device targets, so that the friction can be reduced even more during each calibration.

As described above, according to the video head drum relative speed control circuit and the method according to the present invention, after calculating the feed distance per unit second of the current tape by counting the regeneration control pulse generated when the drum motor rotates in the FF / REW mode By dividing the diameter and circumference of the rotating video head drum to match the speed of the current tape with the speed of the rotating head, it improves tape wear and head wear, extending the life of the head and tape, To prevent contamination of the head and deck.

In addition, the friction coefficient between the video head and the tape is reduced, reducing the load on the capstan motor and deck mechanism that transports the tape, thereby extending the life and reducing the power consumption and facilitating high speed FF / REW.

Claims (3)

A drum frequency generator designed at a predetermined angle on the circumference of the video head drum to generate a sine wave of a predetermined cycle during one rotation of the head drum, and designed at a predetermined position on the circumference of the head drum, A drum phase generator for outputting a pulse waveform of one cycle during rotation, and the speed and phase of the head drum in accordance with the frequency generation signal, the phase generation signal, and the mode designation signal generated by the drum frequency generator and the drum phase generator. A video head drum speed control circuit composed of a controlling servo circuit, comprising: a regeneration control pulse detection means for detecting a regeneration control pulse generated when the head drum rotates in a fast forward / rewind mode, and a regeneration control pulse detection means; Pulse counting means for counting the detected reproduction control pulses, and the pulse count number A tape speed detecting means for calculating a conveying distance of the current tape by multiplying the counted value by the interval between control pulses according to the playback mode of the current tape, and a conveying distance of the current tape calculated by the tape speed detecting means of the head drum. A video head drum relative speed regulating circuit comprising: a drum speed control means for dividing a diameter and a circumferential ratio to calculate a target rotational speed of the head drum and controlling the servo circuit to rotate the head drum at the calculated target rotational speed. 2. The video head drum relative speed adjustment circuit as set forth in claim 1, wherein said pulse counting means counts regeneration control pulses in seconds. In the fast-winding mode, the direction of rotation of the head drum is specified in the forward direction, and in the fast rewind mode, the direction designation process of specifying the rotation direction of the head drum in the reverse direction; A head drum rotation step of rotating the head drum in a predetermined forward or reverse direction at a target rotational speed; a counting step of counting a reproduction control pulse generated when the head drum rotates in the head drum rotation step; A tape feed distance calculation step of calculating a feed distance per unit second of the current tape by multiplying the calculated value by the interval between control pulses according to the playback mode of the tape, and a head drum rotating the tape feed distance calculated in the tape feed distance calculation step. Neck of head drum divided by the diameter and circumference of the The target rotational speed calculation process for calculating the table rotational speed and the drum servo are controlled to rotate the head drum at the target rotational speed calculated in the target rotational speed calculation process to match the speed between the currently moving tape and the rotational head. A video head drum relative speed control method comprising a drum speed control process.