KR100233526B1 - Capstan motor frequency signal counter method of time lapse vcr - Google Patents

Abstract

Disclosed is a method of counting a frequency signal of a capstan motor in a type labs VR, and in the method of counting a frequency signal generated from a frequency signal generator of a capstan motor that is intermittently driven, (1) the capstan motor at a constant speed. Starting to count the frequency signal generated from the frequency signal generator at any point in time of rotation; And (2) determining whether the count value coincides with a preset value, and if it matches, resetting the count value and starting counting again. Such a frequency signal counting method has an effect of accurately adjusting the driving time of the capstan motor at every recording in a time-lapse VC that intermittently records the frequency signal generated from the frequency signal generator of the capstan motor without error.

Description

How to Count Frequency Signals of Capstan Motor in Time Lapse VRC

The present invention relates to a time-lapse V seed, and more particularly, to a method for accurately counting a frequency signal generated from a frequency signal generator of a capstan motor without error.

In general, Time Lapse V-Cal captures scenes intermittently and records them on a videotape at a place where surveillance must be maintained at all times, such as a bank, so that the situation for a long time can be known.

Figure 1 shows a device for counting the frequency signal of the Camston motor in time-lapse VRC. 1 is a counter 11 for receiving and counting a frequency signal (C.FG) generated from a frequency signal generator of a capstan motor (not shown), and receiving a count result to control driving of the capstan motor (not shown). A microprocessor 12 is provided.

FIG. 2 is a diagram for explaining a section in which the frequency signal C.FG of the capstan motor is counted conventionally in the apparatus of FIG. Time Lapse V-Cal records the video taken at a certain time on one track of the video tape. To do this, the capstan motor has to be driven every time as shown in FIG. Here, the driving time of the capstan motor corresponds to the time for moving the video tape by one track.

In order to drive the capstan motor by one track of the video tape, a frequency signal generated from a capstan frequency generator (C.FG) of the capstan motor is used. As shown in FIG. 2, conventionally, the capstan motor is driven and the counter 11 starts to count the frequency signal generated from the frequency signal generator of the capstan motor. The microprocessor 12 which receives the count value from the counter 11 stops the rotation of the capstan motor as soon as the count value matches the preset value. Here, the predetermined value is a time corresponding to an image of one field and is obtained through experiments, and the value is usually “18”.

However, in the time-lapse VSR for intermittent recording, if the capstan motor starts to be counted at the same time as the capstan motor starts to be driven as in the conventional counting method described above, a count error occurs when the capstan motor starts and stops. Could occur.

For example, in the related art, when the capstan motor starts counting at the same time as the start of the capstan motor, when the preset value is reached, the counting ends at the same time as the driving section of the corresponding capstan motor ends, and the count operation is repeated in the second field. Pulses of the first frequency signal and pulses of the first frequency signal of the second field are counted as individual pulses.

However, in FIG. 2, the section between the first field and the second field corresponds to the stop section of the capstan motor. Therefore, the interval between the pulse of the 18th frequency signal counted in the first field and the pulse counted first in the second field corresponds to the above-described stop period, and the level of the 18th pulse of the first field described above is low. It does not fall to) and it just stops. Therefore, the 18th pulse of the first field and the first pulse of the second field must be counted as one pulse including the interval therebetween.

More specifically, when the frequency signal generator for detecting the rotation of the motor stops at the N pole in response to the 18th pulse of the first field, the next time the capstan motor corresponding to the second field is driven, the frequency signal generator is currently stopped. Since the first pulse of the second pulse is generated from one N pole, two adjacent pulses between two fields actually correspond to one pulse.

In general, the driving section of the capstan motor shown in FIG. 2 includes a section in which the capstan motor is started and its speed is accelerated for a predetermined time, a section in which the capstan motor is in a stable driving state, and a constant speed section, and a deceleration section for stopping the capstan motor. Subdivided into In the driving section of the capstan motor having such subdivided sections, the capstan frequency signal in the acceleration section and the deceleration section described above is often not counted properly because the signal level is very small. However, in the conventional capstan frequency signal counting method that starts simultaneously with the start of the capstan motor, the count value is not accurate because the count starts from the beginning of the aforementioned acceleration section and the count ends at the end of the deceleration section.

Therefore, the conventional frequency signal counting method in which the driving of the capstan motor and the counting of the frequency signal of the capstan motor is started at the same time, the count value is not accurate as described above, and thus the reliability is low. This makes it impossible to precisely perform servo control. In particular, when such a count error accumulates, it causes dropouts, and a separate correction process is required to solve this problem, which further impairs the stability of the system and complicates the control method.

An object of the present invention for solving the above problems is to accurately and without error the frequency signal from the frequency signal generator of the capstan motor for accurate intermittent recording in the Type Labs VAL made of alternating drive and stop sections of the capstan motor The present invention provides a method of counting.

1 is a frequency signal counting device of a general capstan motor.

2 is a view for explaining a section for counting the frequency signal of the capstan motor in a general time-lapse VRC.

3 is a diagram showing a frequency signal count section of a capstan motor according to the present invention.

* Explanation of symbols for main parts of the drawings

11 counter 12 microprocessor

The frequency signal counting method of the capstan motor according to the present invention for achieving the above-described method, the frequency of the capstan motor to be driven for a predetermined interval intermittently in the time-lapse V-CAL alternately drive and stop section of the capstan motor A method of counting a frequency signal generated from a signal generator, the method comprising: (1) a frequency signal generated from the frequency signal generator from any point in a period in which the capstan motor is in a stable driving state after the capstan motor is started in the driving section; Starting to count; And (2) determining whether the count value coincides with a value set to correspond to the preset driving section, and if it matches, reset the count value and start counting again.

In addition, the frequency signal counting method of the capstan motor according to the present invention is characterized in that for moving the video tape by one track every time recording in the time-lapse V-CAL performing intermittent recording.

Hereinafter, with reference to the accompanying Figure 3 will be described in detail the frequency signal counting method of the capstan motor according to an embodiment of the present invention.

First, the counting method according to the present invention does not start counting the frequency signal of the capstan motor at the same time as the capstan motor is started, and when the capstan motor is started and becomes a stable driving state after a predetermined time, the stable driving state The above-described frequency signal starts counting at an arbitrary point within the interval, and is reset when the count value reaches a preset value. In addition, the capstan frequency signal counting method of the present invention obtains a count value in which the count error is zero or minimized, compared to the conventional method. Accordingly, the microprocessor can accurately control the driving of the capstan motor based on the accurately obtained count value.

Referring to FIG. 3, the time-lapse VAL has a driving section and a stopping section of the capstan motor alternately, and the driving section is shifted by one track (or one field of the image signal to be recorded) of the video tape. It is preset to correspond. The drive section described above is controlled to have an acceleration section for starting the capstan motor, a constant speed section in a stable driving state of the capstan motor, and a deceleration section for stopping the capstan motor as shown in FIG. Therefore, in the preferred embodiment of FIG. 3, the section in which the aforementioned capstan motor is in a stable driving state is a constant speed section, and the present invention is not limited thereto. For example, the driving section of the capstan motor may be controlled only by the acceleration section and the deceleration section. In this case, the capstan described above is a section in which the signal level of the frequency pulse from the frequency signal generator of the capstan motor exceeds a predetermined value. It is apparent to those skilled in the art from the technical features of the present invention that the motor can be set to a section in which the motor is in a stable state.

On the other hand, in the capstan motor frequency signal counting method according to FIG. 3, when the capstan motor speed reaches the above-mentioned constant speed section, counting starts from an arbitrary point in the constant speed section. Then, the counted value is compared with a preset count value corresponding to 1 track. If the result of the comparison is not reached, the count is continued until the count value is matched, and if it is matched, the counter is reset.

More specifically, in the apparatus of FIG. 1 to which the counting method according to the preferred embodiment of FIG. 3 is applied, the Marekro processor 12 starts at any point in the constant speed section when the capstan motor starts driving and rotates at a constant speed. The counter 11 is reset. In response to the counter reset signal, the counter 11 starts counting pulses of the frequency signal C.FG input from the frequency generator of the capstan motor from the arbitrary point of the constant speed section, and the counted value is described above. Continue counting until you reach politics.

On the other hand, if the capstan motor stops rotating due to the stop section of the capstan motor shown in FIG. 3 while counting the frequency signal, the microprocessor 12 pauses the operation of the counter 11, and at this time, the counter 11 Maintains the value counted to date. Therefore, the stop sections corresponding to the intervals between the adjacent drive sections do not have to correspond to each stop section or the section length with the drive section.

Thereafter, the second drive section shown in FIG. 3 is started, and when the rotation of the capstan motor is resumed, the counter 11 continues counting under the control of the microprocessor 12. At this time, the counter 11 counts the pulse of the capstan frequency signal by adding a value counted in the second drive section to the count value counted and maintained in the first drive section. In particular, since the pulse is counted only at a certain edge of the pulse, the 18th pulse of the first field and the first pulse of the second field shown in FIG. 2 are counted as one pulse.

Subsequently, the microprocessor 12 resets the counter 11 again when the count value reaches "18" which is the preset value, and thus the counter 11 restarts the count from the initial value. Here, when the counter 11 is reset again, the capstan motor is at the corresponding position in the constant speed section of the second drive section, corresponding to the count start position of the constant speed section of the first drive section shown in FIG. It is possible to count the frequency signal of the capstan motor which is predetermined to correspond to this. Particularly, in the present invention, the pulse of the capstan frequency signal is counted in the acceleration section for starting and the deceleration section for stopping in the driving section of the capstan motor, but the corresponding sections are not the conventional count start and end positions, but the total count. Since it is located in the middle of the section, even if the signal level is small, it is possible to minimize the count error by amplifying or estimating the position.

On the other hand, the counting method according to a preferred embodiment of the present invention, the intermittent recording of the type V seedlings, control the driving of the capstan motor so that the video tape is transferred by a predetermined one track (or one field of the image) for each intermittent recording It is useful to In particular, in the present invention, since the driving start time and the end time of the capstan motor do not coincide with the count start time and end time of the counter, the microprocessor is measured by measuring and correcting the time difference between the driving sections with respect to the aforementioned count section at the time of system initialization. 12 can precisely control the driving of the capstan motor. According to the embodiment described above, if the microprocessor 12 drives or stops the capstan motor after the above-described time difference from the time when the count value becomes “18”, the count value is reliable. Because of this value, it is possible to accurately control the driving time of the capstan motor.

As described above, the frequency signal counting method according to the present invention and the frequency signal generated from the capstan motor are counted from an arbitrary point in the stable driving section to a predetermined value instead of the starting point of the capstan motor, thereby providing a V for intermittent recording. Capstan frequency signal corresponding to the predetermined drive section to be used for the seed can be accurately measured without error. Accordingly, the present invention provides an effect of accurately controlling the driving of the capstan motor during every recording in the time-lapse V seedling performing intermittent recording.

An object of the present invention is to accurately count a frequency signal generated from a frequency signal generator of a capstan motor in a time lapse VCR for recording one field of video in a stepwise manner so that the video tape is accurately recorded every recording. The present invention provides a method for counting frequency signals that can be moved by a field.

Claims (2)

A method of counting a frequency signal generated from a frequency signal generator of a capstan motor which is driven for a predetermined period intermittently in a time-lapse VAL in which a driving section and a stopping section of a capstan motor are alternately provided, (1) the driving section Starting the counting of the frequency signal generated from the frequency signal generator from an arbitrary time point in the stable driving state after the capstan motor is started; And (2) determining whether the count value coincides with a value set to correspond to the predetermined driving section, and if it matches, resetting the count value and starting the count again. The driving section is an acceleration section for starting the capstan motor, a constant speed section in the stable driving state, and a deceleration section for stopping, and the step (1) is performed in any of the constant speed section. The count is started from the point of time, and the step (2) is reset at the corresponding position of the constant speed section in the next drive section corresponding to the count start position, and then resets the drive section starting the count and the count. A method for counting frequency signals of a capstan motor, characterized in that the count value in the driving section in which the counting starts is maintained in the stop section between the driving sections.