KR19990042611A - Break detection control method of VSI tape - Google Patents

Abstract

The present invention relates to a break detection control method for a VSI tape. In the related art, when the tape is broken while the tape is inserted into the deck, the tape is not wound properly on the supply reel or take-up reel so that both ends of the detection sensors The output does not appear constant, and only one start sensor or end sensor is operated, or two sensors are repeatedly turned on or off irregularly, resulting in a time delay in determining tape break and making it difficult to make a quick judgment. There was a problem.

According to the present invention, if the system microprocessor determines whether there is an active output of both the start sensor and the end sensor, and if both have an active output, driving the eject mode (steps 101 and 102), and all the sensors do not generate an active output. If only one is detected, the controller checks whether a reel error is detected or performs normal operation (steps 104 and 105), and if the reel error is executed, executes the eject mode and continues to perform a specific mode (step 106). The present invention provides a method of controlling the break detection of a VSI tape including the back.

According to the present invention, there is an effect that the system can automatically determine that the tape is inserted into the deck and obtain appropriate measures accordingly.

Description

Break detection control method of VSI tape

The present invention relates to a tape break detection control method in VSI, and more particularly, when a tape in a cassette tape margin loaded into a deck is broken in a normal state or breaks while driving, the system automatically determines the tape margin. By allowing them to be ejected, this set of deck and tape damage is reduced.

VCR (VCR) is a device that records the video signal input from the outside or the video signal of the over-the-air broadcasting received through the internal TV tuner on the video tape, and also outputs the video signal recorded on the video tape through the television screen Known as

The odometer for recording and reproducing the video signal of VSI shows this as shown in FIG. 1.

In the case of the VHS standard method, two video heads are mounted on the side surface of the rotating drum 11 having a diameter of 62 mm at intervals of 180 °, and the rotating drum 11 is used every second. You have 30 turns.

In addition, the video tape 12 travels in a state in which the rotating drum 11 is wound by 180 ° or more, and the rotating drum 11 is mounted on the tape which is inclined with respect to the deck base and runs parallel to the deck base. It is wound inclined against.

A tape guide 13 for guiding the video tape 12 is provided in the lower cylinder of the rotating drum 11 fixed to the deck base, and the tape is moved upward and downward at a position approaching the tape guide 13. In order to prevent the video head from being able to accurately trace the video track as it moves, the respective loading posts 14 and 15 are provided on the supply side and the take up side of the head drum.

The loading posts 14 and 15 draw and move the video tape 12 at the time of tape loading, which are made by pairs of inclined posts and posts perpendicular to each other.

Impedance rollers may be installed on both sides of the tape supply side and the take-up side passing through the loading posts 14 and 15 from the rotating drum 11, respectively. This impedance roller has a function of stabilizing the tape running and partially improving the jitter phenomenon in which the screen shakes due to the shaking of the playback signal.

Thus, when looking at the running process of the tape, the video tape 12 withdrawn from the supply reel 16 of the tape cassette comes into contact with the full-width erasing head 19 via the tension arm and the back tension post 18. The full-width erasing head 19 receives the high frequency signal current supplied from the OSC at the time of signal recording and erases the video signal recorded on the tape.

The tape is then recorded by the video head in the rotating drum 11 via the loading post 14 on the supply side and then through the loading post 15 on the take up side. The video tape 12 which has passed through the loading post 15 reaches the mute head 22 and the voice and control heads 21 and 20.

Since the oscillation signal of the OSC supplied to the full-width erasing head 19 is supplied as it is only during voice dubbing, only the voice signal recorded on the voice track of the video tape 12 is erased. .

The voice and control heads 21 and 20 have a control head 20 disposed below them and a voice head 21 disposed above them to record and reproduce voice and control signals on respective tracks. The voice mute head is not used in the normal case because there is a full width mute head 19, and is used only during the voice dubbing operation.

Then, the video tape 12 supplied from the supply reel 16 is wound around the take-up reel 17 through the capstan motor 24 and the pinch roller 23 for stably running the tape.

In such a tape running system, since the erasing current and the video signal are simultaneously supplied to the full-width erasing head 19 and the video head at the time of recording the video signal, the video of the portion located between the full-width erasing head 19 and the video head is simultaneously supplied. The tape 12 records the new video signal repeatedly as it is without erasing the previous recording. To prevent this, the system control micom compensates the tape and the mileage as mentioned above every time the tape is loaded. In order to control the backward driving of a certain section automatically.

Since the occurrence of the image overwrite section on the video tape 12 also appears at the start portion of the tape, the tape may be recorded even when the video signal is to be recorded from the start point of the tape using the video tape 12 on which any video signal is recorded. In order to execute the tape rewind mode at the time of loading, the video tape 12 wound on the take-up reel 17 side must be sent to the supply reel 16 side.

In the first portion of the take-up reel 17 and the supply reel 16, unlike the magnetic tape coated video tape 12, the transparent tape which is not coated with the magnetic material is wound several times.

Therefore, in the transparent tape section which is wound on the first part of the reel, the light emitted from the light emitting element 25 of the photosensor disposed with the tape interposed therebetween starts sensor 27 or end sensor which is a light receiving element through the transparent tape section. Since it is projected as it is to be recognized as (26), through this it is possible to determine whether the tape start and end or it is possible to determine the break of the tape.

In this way, when the start point of the tape is sensed by the start sensor 27 and transmitted to the microcomputer, the microcomputer controls the drum drum and the capstan servo to control the rotating drum 11 and the capstan motor 24.

After the image recording mode is executed, the full-width erasing head 19 is applied with the tape erasing oscillation signal and the video head is simultaneously applied to record the video and audio signals on the video tape.

Looking more specifically at the end detection operation of the tape in this prior art, the start sensor 27 or end sensor 26 at the transparent tape position at the beginning or end of the tape when the tape is wound in any direction as the tape travels. When the tape end is detected and the tape end is detected, the control unit recognizes the end detection signal and stops the tape from running any further, and controls the capstan motor to release the end detection. Each end detection sensor may be released by rotating the capstan motor forward to release and reversely rotating the capstan motor to release the end sensor when the end sensor is operated.

The control unit checks such a conventional end detection sensor and determines that the tape is broken when both the start sensor and the end sensor operate, and ejects the tape. When the start sensor only or the end sensor operates, As in the operation, once the end detection sensors are released, it is determined whether the end detection sensors are operated again, and it is determined that the tape is broken only when the outputs of the two sensors are present at the same time.

However, if the tape is detected by the conventional method as described above, the tape is not wound properly on the supply reel 16 or the take-up reel 17 when the tape is actually broken. This operation does not appear constantly, and in practice, only one start sensor 27 or end sensor 26 is operated, or two sensors are turned on or off irregularly. This results in a time delay in determining tape breaks. This is followed by a problem that is difficult to quickly judge.

It is an object of the present invention to solve the conventional problems as described above, the tape is loaded into the deck so that both the start and the end sensor is not active driving, even if only one of the operation is to determine whether the tape breaks according to the reel error In such a system, more accurate tape breaks can be determined.

According to the present invention, the system microprocessor determines whether there are active outputs of both the start sensor and the end sensor so as to realize the above object, and if both have active outputs, driving the eject mode, and all the sensors are active. Checking whether it is a reel error if only one is detected without generating an output, or performing a normal mode; and if the reel error is performed, executing an eject mode or continuing to perform a specific mode. It is characterized by the method of controlling break detection of VSI tape.

1 is a perspective view schematically showing a tape traveling system of a general VSI;

2 is a system circuit block diagram related to the present invention.

Figure 3 is an embodiment of a tape break detection control program of the present invention

* Description of the symbols for the main parts of the drawings *

31: microprocessor 32: reel sensor

33: reel motor drive unit 34: start sensor unit

35: end sensor portion 36: deck portion

Hereinafter, specific features of the present invention will be more readily understood by explaining the present invention in detail with reference to the accompanying drawings.

Figure 2 shows an excerpt of the system circuit block related to the present invention.

Here, the microprocessor 31 which performs a system control operation, the deck part 36 which performs a deck operation | movement under control of this microprocessor 31, and the winding of the tape loaded in the deck part 36 are performed. The reel motor driver 33 and the like are connected to the microprocessor 31.

In addition, the system includes a reel sensor unit 32 installed on the reel motor of the reel motor driving unit 33 for detecting a reel rotation state, a start sensor unit 34 for detecting an initial transparent portion of the tape, and a tape end. The end sensor unit 35 for detecting is included.

In addition, the system is provided with a tape break detection control program 100 as shown in FIG.

In this case, the system microprocessor 31 determines whether there are active outputs of both the start sensor and the end sensor, and if both have an active output, driving the eject mode (steps 101 and 102), and all the sensors output the active output. If only one is detected and it is not generated, it is checked whether it is a reel error, or if it is performed in the normal mode (steps 103 to 105) and the like.

In the case of the reel error described above, an eject mode is executed or a specific mode is continued (step 106).

According to the present invention configured as described above, when the video signal is to be recorded from the start point of the tape using the video tape 12 on which a predetermined program video signal is recorded as shown in FIG. 1, the tape rewind mode is executed when the tape is loaded. The video tape 12 wound on the reel 17 side is always sent to the supply reel 16 side.

In the first portion of the take-up reel 17 and the supply reel 16, unlike the magnetic tape coated video tape 12, the transparent tape which is not coated with the magnetic material is wound several times.

Therefore, in the transparent tape section which is wound on the first part of the reel, the light emitted from the light emitting element 25 of the photosensor disposed with the tape interposed therebetween starts sensor 27 or end sensor which is a light receiving element through the transparent tape section. Since it is projected as it is to be recognized as (26), through this it is possible to determine whether the tape start and end or it is possible to determine the break of the tape.

In more detail, when the tape is rolled in any direction as the tape runs, the start sensor 27 or the end sensor 26 operates at the transparent tape position at the beginning or the end of the tape so that the tape end is When detected, the control unit recognizes the end detection signal, stops the tape from running any further, and controls the capstan motor to release the end detection. When the start sensor is operated, the capstan motor ( 24 is rotated forward, and when the end sensor operates, the capstan motor 24 is reversed to release the end sensor, thereby releasing the respective end detection sensors.

In this way, when the start point of the tape is sensed by the start sensor 27 and transmitted to the microcomputer, the microcomputer controls the drum drum and the capstan servo to control the rotating drum 11 and the capstan motor 24.

As the tape is broken while the tape is running as described above, the tape is not wound properly on the supply reel 16 or the take-up reel 17 when the tape is broken. This does not appear constantly, and in practice, only one of the start sensor 27 or the end sensor 26 is operated, or an operation in which both sensors are irregularly turned on or off is repeated.

Therefore, in this state, the microprocessor 31 of FIG. 2 shows the deck when only one of the start sensor unit 34 and the end sensor unit 35 detects an active input and detects a reel motor abnormality from the reel sensor unit 32. By running section 36 in the eject mode, the eject mode for accurate tape break can be executed.

This operation is performed by the microprocessor 31 in conjunction with the tape break detection control program 100 as shown in FIG. 3. The system microprocessor determines whether there is an active output of both the start sensor and the end sensor. If so, the eject mode is driven (steps 101 and 102).

If all of the sensors do not generate an active output and only one of them is detected, the controller checks whether a reel error is detected or performs normal operation. If the reel error is detected, the eject mode is executed or the specific mode is continued. (Steps 103 to 106).

The present invention can solve the conventional problem that the tape was broken while the tape is running while the tape break is not accurately detected in the state where only one of the start sensor and the end sensor is detected, thereby realizing more reliable and accurate system operation. will be.

Claims (1)

The system microprocessor 31 includes a start sensor and a start sensor unit 34, an end sensor unit 35, a reel sensor unit 32, a deck unit 36, a microprocessor 31, and the like. It is determined whether there are active outputs of both end sensors, and if both have active outputs, driving the eject mode (steps 101 and 102), and is a reel error when only one of the sensors is detected without generating an active output. Check or otherwise perform the normal mode (step 104, 105), and if the reel error above, execute the eject mode or continue to perform a specific mode (step 106), etc. How to control tape break detection