KR890004419B1 - Video signal recording apparatus - Google Patents

Abstract

The recorder is to shorten the pull-in time during which the prescribed relation is secured between the revolving phase of a rotor and the phase of a phase reference signal in a start mode. The signal obtained by giving N-division to the output signal of a frequency generator (FG) by an N-division circuit (12) is used as the sampling signal of a phase comparator (11), while a phase reference signal uses the output of the second synchronous generator (13). The output of the comparator (11) is checked by a phase pull-in detecting circuit (14) to detect that the prescribed relation is secured between the phase reference signal and the output phase of the circuit (12).

Description

Video signal recording device

1 shows a track pattern of a video floppy;

2 is a block diagram of motor control of a conventional video signal recording apparatus.

3 is a block diagram of a motor controller of an image signal recording apparatus according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

8: Moter 10: to speed comparison church

11: phase comparison circuit 13: second synchronization signal generating circuit

14: phase synchronization inlet detection circuit 15: first synchronization signal generation circuit

16: reference phase setting signal generating circuit

The present invention relates to rotation phase control of a video signal recording apparatus.

In a video signal recording apparatus, for example, a video floppy, when a disc-shaped magnetic sheet is driven by a motor to record a video signal on the magnetic sheet, as shown in FIG. The phase relationship between the yoke (PG yoke) of the rotating pulse generator (hereinafter referred to as PG) and the leading edge of the vertical synchronization signal (hereinafter referred to as Vsync) of the video signal is maintained at a predetermined angle θ. You must.

As described above, in the video signal recording apparatus, it is necessary to control the motor and the like so as to maintain the rotational phase of the rotational recording medium driven by the motor and the like and the phase of the signal to be supported by the rotational phase in a predetermined relationship. . This conventional control method will be described based on FIG.

The conventional control method comprises a speed control means for keeping the rotation speed constant and a phase control means for matching the phase of rotation of the rotating body to the phase reference signal.

First, the speed control means will be described. By comparing the output signal of the signal generating means proportional to the rotational speed of the motor 1, for example, the frequency generator 2 (hereinafter referred to as FG) and the frequency of the speed reference signal in the speed comparator 3, Output the signal according to the difference of frequency. When the output frequency of the FG (2) is higher, a signal that lowers the rotational speed of the motor is output, and when the output frequency is lowered, an output signal that raises the rotational speed of the motor is output to make the rotational speed of the motor constant. I can keep it. Next, the phase control means will be described. The phase comparison signal of the rotation phase detector of the rotating recording medium driven by the motor 1, for example, the output signal of the PG 4, and the phase reference signal obtained from the synchronization signal generating circuit 5, can be used as a phase comparison circuit (6). In comparison with), a signal according to the phase difference is output, and the motor 1 is rotated to match the phase of the phase reference signal and the PG signal.

As mentioned above, the speed control means and the phase control means were put together, and the rotational phase of the rotating recording body and the phase of the phase reference signal were adjusted in a predetermined relationship.

However, this method had the following problem. For example, when recording NTSC video signals on a disc-shaped magnetic sheet for one week, the rotational speed is maintained at 60 [rps], and the rotational phase of the rotational recording medium is set to the phase of the reference signal and a predetermined value. You need to control it to keep it in a relationship. Normally, Vsync is used as the reference signal of the phase control circuit 6 of the phase control, Vsync is 60 Hz], and the phase comparison is performed whenever a PG signal is generated. 60 Hz]. In order to operate the control system stably, considering the effects of phase delay due to sapling of phase comparison, the cutoff frequency (hereinafter referred to as fc) must be set to 1/10 or less of fs. In this case, fc is Vsync. 1/10 or less, i.e., 6 [Hz] or less. By the way, the synchronous pull-in time of the control system at the start takes longer as fc is lower, and takes 1 second or more when the actual fc is about 6 [Hz]. In order to increase fc, fs must be increased. However, in this case, fs is limited by the frequency of Vsync, which in turn makes it difficult to shorten the phase control synchronization entry time at startup.

In particular, in order to reduce the current consumption, in the apparatus for starting the motor immediately before recording a signal, the phase control synchronous insertion time at the start, that is, the starting phase and the phase of rotation of the rotating recording body and the phase of Vsync are determined. The shortening of the time until it became a recordable state was a big problem.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems, and aims to shorten the synchronous retracting time until the rotational phase of the rotating body and the phase of the phase reference signal become a predetermined relationship during startup.

According to the present invention, there is provided a first synchronization signal generating means capable of generating a synchronization signal for recording a video signal, which can be set to a reference phase by an external signal, and a signal proportional to the rotational speed of the rotating recording medium for recording the video signal. First signal generating means for generating a signal, means for dividing the output of the first signal generating means (N 1), second synchronizing signal generating means for generating a phase reference signal of the N division output, and A phase control means for matching the phase of the N division output and the phase reference signal to a predetermined relationship, phase synchronization retrieval detection means for detecting that the phase of the N division output and the phase reference signal has a predetermined relationship; Rotation phase detection means for detecting a rotational phase of the rotation recording body, and detection by means of the phase synchronization inlet detection means that the phase of the N division output and the phase reference signal have a predetermined relationship. And then, by setting the first synchronization signal generating means to at least one reference phase by the rotation phase detection means output or an output delaying the output for a predetermined time, the synchronization signal for recording the video signal, and An image signal recording apparatus comprising means for matching the rotation phase of a rotation recording body to a predetermined relationship.

In the present invention, the speed control means, the phase control means, and the video signal are recorded in order to maintain the rotational phase of the rotational recording medium driven by a motor or the like and the phase of the signal which is the reference of the rotational phase in a predetermined relationship. Means for generating a synchronization signal to set the reference phase.

An embodiment of the present invention will be described using FIG.

First, the operation of the speed control means, as in the conventional apparatus, compares the output proportional to the rotational speed of the motor 8, that is, the output of the FG 9 and the frequency of the speed reference signal in the speed comparator 10. Thus, the motor 8 is driven in accordance with this output to keep the rotational speed constant.

Next, the operation of the phase control means will be described. As the sampling signal of the phase comparator 11, a signal obtained by dividing the output signal of the FG by the N division circuit 12 from the N division N 1 is used, and the phase reference signal of the second synchronization signal generation circuit 13 is used. Use output In this case, when FG generates Z pulses for each rotation of the rotating recording body, and the rotating recording body rotates at n (rps), the frequency fr [Hz] of the phase reference signal becomes fr = Z × n ÷ N. Must meet. The rotation of the motor 8 is controlled so that the phase becomes a predetermined relationship by comparing the output of the N division circuit 12 having the above relation and the phase relationship of the phase reference signal in the phase inversion circuit 11. do.

Here, if fr is higher than the frequency of Vsync, it goes without saying that the time required to bring the phase into a predetermined relationship can be shorter than that of the conventional apparatus.

By the way, when recording a video signal on a rotating recorder driven by a motor or the like, the phases of the PG signal and the Vsync must be in a predetermined relationship. In this embodiment, only the speed control means and the phase control means are used. Since the PG signal and Vsync are not considered at all, the phase relationship between these two signals is not determined at all. Thus, by checking the output of the phase comparator 11 in the phase synchronization inlet detection circuit 14, it is detected that the phase of the phase reference signal and the output of the N division circuit 12 have a predetermined relationship, and immediately after the detection. The first synchronization signal generation circuit 15 generating Vsync by the first PG signal or a signal delaying the PG signal by a predetermined time is determined as the reference phase. As a result, the phase of the Vsync generated in the first synchronization signal generation circuit 15 and the phase of the PG signal can be forcibly prescribed.

Next, for example, a control method using the present embodiment in the case of driving a rotating body at a speed of 60 [rps] using an FG configured to generate 65 pulses every time the motor rotates is specifically described. Explain. The frequency of the FG signal is 3900 [Hz], and a signal divided by two is used as a sampling signal for speed comparison. As a result, fs becomes 1950 [Hz]. Since fc must be 1/10 or less of fs, that is, 195 [Hz] or less, the synchronous pulling-in time of speed control is about 30 [msec].

In addition, fc of the phase control means should normally be about 1/5 or less of fc of the speed control means in consideration of the phase margin and the control margin of the control system, and in this case, it should be 39 [Hz] or less. . Therefore, it is necessary to set fs to the phase comparator at least 10 times of fc, that is, at least about 390 [Hz]. Here, a signal obtained by dividing the FG signal by eight is regarded as a sampling signal, and fs is 487.5 [Hz]. The phase reference signal is assumed to be obtained from the second synchronization signal generation circuit. As a result, the synchronous pull-in time of phase control will be about 130 [msec]. In addition, between the rotational speed n = 60 [rps], the number of pulses generated by FG in one rotation, Z = 65, the N, N = 8 phase reference signal of the frequency divider circuit, and fr = 487.5 [Hz], Satisfying relationships.

fr = Z × n ÷ N

Next, the operation of the reference phase setting means will be described. This is to detect that the phase control is synchronously inserted in the phase synchronization inlet detection circuit 14, and then set the first synchronization signal generation circuit as the reference phase with the minimum PG signal. In this case, since the frequency of the PG signal is 60 [Hz], the time required for detecting the first PG signal and setting it to the reference phase after phase synchronous inlet detection is up to 17 msec.

As a result, after the motor is turned on, the phase synchronization induction time until the phase of the PG signal and the Vsync becomes a predetermined relationship can be set to about 180 [msec].

As described above, in the present embodiment, since the divided output of the FG signal is used as the sampling signal of the phase control means, it is possible to set fs without being limited to the frequency of Vsync as in the conventional example, so that fc is also conventional. As an example, less than one tenth of the frequency of Vsync can be higher than the frequency. For this reason, even if it adds time until the phase of a PG signal and a Vsync are made into a predetermined relationship, the synchronous pull-in time of a phase control means can be cut out more significantly than before.

Here, as long as the phase reference signal 11 has a predetermined relationship between the phase reference signal and the N division signal of the FG signal, the phase relationship between the PG signal and Vsync determined once does not change. When the phase of the phase reference signal and the N-divided signal of the FG signal deviate from a predetermined relationship due to a large disturbance, the first synchronization is established. By setting the signal generation circuit 15 to the reference phase again, the predetermined phase relationship can be maintained.

As described above, according to the present embodiment, phase control means for making a predetermined relationship between the N division output of the FG signal and the phase reference signal obtained by the second synchronization signal generation circuit 13 and the phase have a predetermined relationship. And a means for detecting that the first synchronization signal generation circuit that generates Vsync is set to at least one reference phase at the time of starting by detecting that the PG signal or the PG signal is delayed by a predetermined time. The rotational phase of the rotating recording body and the phase of the Vsync can be made in a predetermined relationship in a shorter time than in the prior art. In addition, when it is detected that the phase reference signal and the phase of the sampling signal have a predetermined relationship, the first synchronization signal generation circuit 15 is set to the reference phase using the first PG signal immediately after the detection. If the phase of the phase reference signal and the sampling signal has a predetermined relationship, the phase of the PG signal and the Vsync are set at least once with a PG signal other than the first PG signal immediately after the detection. Not to mention that. In addition, although the original oscillation circuit of the 1st synchronous signal generation circuit 15 and the 2nd signal generation circuit 13 is common, you may use each original oscillation circuit.

According to the video signal recording apparatus of the present invention, it is possible to greatly shorten the sync entry time until the rotational phase of the rotating recording body and the phase of the Vsync become a predetermined relationship at the start. In particular, in order to reduce power consumption, in a device that starts a motor immediately before recording a video signal, the time can be greatly shortened until the recording becomes possible after the motor is started, and thus the practical effect of the present invention. Is absolute.

Claims (5)

Generating a synchronous signal for recording the video signal, and generating a first synchronous signal generating means 15 which can be set to the reference phase by an external signal, and a signal proportional to the rotational speed of the rotating recording medium for recording the video signal; First signal generating means for generating, means 12 for dividing N1 the output of the first signal generating means, and second synchronizing signal generating means for generating a phase reference signal of the N divided outputs; (13), phase control means for making the phases of the N division outputs and the phase reference signal have a predetermined relationship, and phase synchronous insertion for detecting that the phases of the N division outputs and the phase reference signal have a predetermined relationship; The phase synchronization inlet detecting means 14 detects that the detection means 14 and the phase of the phase reference signal have a predetermined relationship, and then delays the output of the rotational phase detection means or the output for a predetermined time. On signal Means for setting the first synchronizing signal generating means to at least one reference phase, and for synchronizing the synchronizing signal for recording the video signal with the rotational phase of the rotating recording body in a predetermined relationship. Video signal recording device. 2. The method according to claim 1, wherein after the first synchronization signal generating means is set to the reference phase, the phase synchronization inlet detecting means detects that the phase of the N division output and the phase reference signal are out of a predetermined relationship. And detecting that the phase synchronization retrieval detection means has reached a predetermined relationship and setting the first synchronization signal generating means to at least one reference phase. The video signal recording apparatus according to claim 1, wherein the second synchronizing signal generating means issues an output having a frequency higher than that of the first synchronizing signal generating means. The video signal recording apparatus according to claim 1, wherein the synchronizing signal for recording the video signal is a vertical synchronizing signal of the video signal. The video signal recording apparatus according to claim 1, wherein the first oscillation circuit of the first synchronization signal generating means and the second synchronization signal generating means is used in common.

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