JPS61150477A - Video disk reproducer - Google Patents

Abstract

PURPOSE:To eliminate jitters produced by the special reproduction of a CLV video disk and the revolving variance of the disk by providing a frame memory to a video disk reproducer to perform the reproduction. CONSTITUTION:The signals recorded on a video disk 1 are read by a pickup 3 and processed at a signal processing part 4. Then the pictures are displayed on a monitor 5. In a standard reproduction mode, only a switch 6B is closed among switches 6 and the processed video signal 7 is projected directly on the monitor 5. While in a special reproduction mode the signal 7 is stored once in a frame memory 8 and then shifted to the monitor 5 for display. When the pickup 3 is jumped over a track during a special reproduction mode,a track jump number arithmetic part 9 decides the number of tracks to be jumped over from the frame number of the video signal 7A which is presently read out by the pickup 3 as well as the frame number of the video signal 7B which is presently reproduced at the monitor 5.

Description

[Detailed description of the invention] [Technical field of invention] The present invention relates to a video disc playback device.

[Technical background of the invention and its problems] Video discs are roughly divided into two types, depending on how information is recorded: constant angular velocity (hereinafter abbreviated as CAV) discs and constant linear velocity (hereinafter abbreviated as CLV) discs. Ru. Among these, on the CAM disk, the image scanning start points are recorded in a straight line in the radial direction, so in this part,
Just make the pickup jump on the track, stand still,
Special playback such as slow motion, double speed, and reverse playback is possible. On the other hand, in a CLV disk, among the disks,
Recording is performed so that the linear velocity is constant regardless of the outer circumference, so when playing back this, the rotation speed becomes slower toward the outer circumference, and the image scanning start point is aligned in a straight line like a CAV disc. There is no line up. For this reason, when conventionally playing back a CLV disk, even if the pickup was caused to jump to a track, the signals read before and after the jump could not be synchronized, making it impossible to perform special playback similar to that of a CAM disk.

[Object of the invention] The present invention has been made in consideration of these circumstances, and
It is an object of the present invention to provide a video disk reproducing device capable of realizing special reproduction and obtaining reproduced images with little jitter.

[Summary of the Invention] According to the present invention, a video disk reproducing device is provided with a frame memory, and after storing an image signal in the frame memory, the image signal is supplied to a monitor to obtain a reproduced image.

[Effects of the Invention] Thus, according to the present invention, by reproducing using a frame memory, for example, CL
Special playback of V-video discs becomes possible. Furthermore, by temporarily storing the image signal in a frame memory and reproducing it, jitter caused by uneven rotation of the disk can be removed.

[Embodiments of the Invention] Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a schematic configuration of main parts of the implementation command device. The video disc (1) is rotated by a motor (2). A pickup (3) reads a signal recorded on a video disk (1), processes it in a signal processing section (4), and projects an image on a monitor (5).

When performing standard playback, only the switch (6B) of the switches (6) is closed and the signal-processed video signal (7)
The video signal (7) is directly displayed on the monitor (5), but when performing special playback, the video signal (7) is temporarily stored in the frame memory (8) and then transferred to the monitor (5). Also, when making the pickup (3) jump to the track during special playback,
The video signal that the pickup (3) is currently reading (
The number of tracks to be jumped to is calculated from the frame number of the video signal (7A) currently being reproduced on the monitor (7B) and the special reproduction command in a track jump number calculating section (9).

Switch (6) is used to smoothly perform special playback. FIG. 2 is a flowchart showing a method for reproducing still images using the apparatus having the configuration shown in FIG. When receiving a still image playback command from an external source, the video signal (7^
), the switch (6A) is closed in synchronization with the image scanning start point that comes immediately after the still image reproduction command is received, and the signal for one frame is taken into the frame memory (8A). At this time, since the switch (6B) remains closed, the same signal as that captured in the frame memory (88) is simultaneously reproduced on the monitor (5). After capturing the signal for one frame into the frame memory (8^), open the switches (6A, 6B) in synchronization with the image scanning start point of the video signal (7^) that comes immediately after that, and open the switch (6D). ) close. By doing so,
Since the frames stored in the frame memory (8^) continue to be played back on the monitor (5), it is possible to play back still images.

FIG. 3 is a flowchart showing a method for performing slow motion playback using the apparatus having the configuration shown in FIG. The video signal (7) that was being played when a slow motion playback command was received from the outside is assumed to be the (ni)th frame. Switch in synchronization with the image scanning start point of n-framero (6^)
is closed, and outputs to the monitor (5) while capturing n frame rows into the frame memory (8A). and (n+1)
Switch (6) in synchronization with the image scanning start point of the frame
A, 6B) are opened and switches (6C, 6D) are closed. While the (n+1)th frame is loaded into the frame memory (8B), the n frame number stored in the frame memory (8A) is displayed on the monitor (5). ). Then, the switch (6C) is opened in synchronization with the image scanning start point of the (n+2)th frame. In this way, the frame memory (8A) stores the n-th frame low signal, the frame memory (8B) stores the (n+1)th frame signal, and the monitor (5) stores the frame memory (8
The n-frame image stored in A) will be output.

This state continues for a while, and after a time t corresponding to the slow motion speed, it is synchronized with the image scanning start point of the video signal (7B), that is, the n frame ro signal output from the frame memory (8A). , switch (6D
) and close the switch (6F). As a result, the output image to the monitor (5) changes from n frame row to (n+1).
Switch to frame number. Next, in order to capture the (n+2)th frame into the frame memory (8^), the pickup (3) must jump to the track where the signal of the (n+2)th frame is recorded. The method is to calculate the number of track jumps from the frame number of the video signal (7A) that the pickup is currently reading and the frame number of the video signal (7B) that is currently being played back on the monitor, and then move the pickup (3) accordingly. It is also possible to make a track jump, and from the time the signal of the (n+1)th frame is taken into the frame memory (8B),
The pickup (3) may continue to jump to the track where the (n+2)th frame signal is recorded. The switch (6A
), the signal of the (n+2)th frame is taken into the frame memory (8A), and the switch (68) is opened in synchronization with the image scanning start point of the (n+3)th frame.

Then, the output image of the monitor (5) is displayed from the nth frame (
One hour after switching to the n+1)th frame, open the switch (6F) in synchronization with the image scanning start point of the (n+1)th frame output from the video signal (7B), that is, the frame memory (8B), Switch (6D)
Close. By doing so, the output image of the monitor (5) is switched from the (n+1)th frame to the (n+2)th frame. By repeating these steps thereafter, slow motion playback can be performed. At this time, by changing the time t, frame-by-frame playback can be performed by providing an external signal instead of the time t as the timing for switching the output image to the monitor (5) during slow motion playback. Roughly speaking, by setting the pickup (3) to track jump in the direction in which the frame number decreases, reverse slow motion and reverse frame-by-frame playback can be performed.

FIG. 4 is a flowchart showing a method for performing double-speed playback using the apparatus having the configuration shown in FIG. The video signal (7) that was being played when the double speed playback command was received from the outside is (n-
1) Set it as the frame. Close the switch (6A) in synchronization with the nth frame image scanning start point, and monitor (5) while capturing the nth frame into the frame memory (8^).
Output to. The switches (6A, 6B) are opened in synchronization with the image scanning start point of the (n+1)th frame, and the switch (60) is closed. As a result, the n-th frame stored in the frame memory (8A) is played back on the monitor (5). Then, the number of track jumps is determined from the frame number (n+1) of the signal currently being read by the pickup and the frame number (n+1) to be reproduced next, and the pickup (3) is caused to track jump. (n
+1) Synchronize with the image scanning start point of the th frame, close the switch (6C), import the (n+1)th frame into the frame memory (8B), and synchronize with the image scanning start point of the (n0m+1)th frame. to open the switch (6C). Next, the switch (6'
D) and close switch (6E). As a result, the output image of the monitor (5) switches from the nth frame to the (n+1)th frame. The frame number you want to play next (
n+2m) and the frame number of the video signal (7A) currently being read out by the pickup (3), the number of track jumps is determined to be 1, and the pickup (3) is caused to jump to the track. Then, in synchronization with the image scanning start point of the (n+2m)th frame of the video signal (78),
) and save the (n+2m)th frame to the frame memory (
8A) and open the switch (6^) in synchronization with the image scanning start point of the (n+2m+1)th frame. Next, in synchronization with the video signal (IB) currently being played, that is, the (n+1)th frame image scanning start point,
) and close the switch (6D). As a result, the output image of the monitor (5) is changed from the (n+1)th frame to the (n+
2m) Switch to frame 2. By continuing the same procedure thereafter, playback can be performed at approximately (m-2) times the speed in a pseudo manner, although there are some differences depending on the access time of the player.

Furthermore, if m is a negative number, double-speed reproduction in reverse is possible. By using the frame memory (8) in this way, C
Special playback of LV video discs becomes possible.

[Other Embodiments of the Invention] FIG. 5 is a block diagram showing a schematic configuration of main parts of an apparatus according to another embodiment of the invention. The video disc (11) is rotated by a motor (12). Video disc (11)
The signal recorded above is read by a pickup (3), processed by a signal processing section (14), and then taken into a frame memory (18) and then displayed as an image on a monitor (15). When performing standard playback, press the switch (1
6^, 16B) should be on the a side.

When making the pickup (13) track jump during special playback, the frame number of the video signal (17A) currently being read by the pickup (13) and the frame number of the video signal (17B) currently being played back on the monitor (15). The track jump number calculation unit (19) determines how many tracks should be jumped from this and the special play command.

To reproduce a still image with the apparatus having the configuration shown in FIG. 5, the switch (16A) is set to position b in synchronization with the image scanning start point that comes immediately after receiving the still image reproduction command. In this state, still images can be reproduced by outputting the frames stored in the frame memory (18A) to the monitor (15).

FIG. 6 is a flowchart showing a method for performing slow motion playback using the apparatus having the configuration shown in FIG. Assuming that the video signal (17B) that was being played when receiving a slow-motion playback command from the outside is the (ni)th frame, the video signal (178) loaded into the frame memory (18A) at that time is the nth frame. This will be the frame. At the video number (178), switch (16A) is switched from a to C in synchronization with the image scanning start point of the (n+)th frame, and the switch (16A) is turned off at the image scanning start point of the (n+2)th frame. Switch from C to b. As a result, the monitor (15) outputs the n-th frame image stored in the frame memory (18A) while displaying frame memo 1.
, 1 (18B) can capture the signal of the (n+1)th frame.

In this state, after time t, the switch (16B) is switched from a to b in synchronization with the image scanning start point of the video signal (17B).
By switching to , the output image of the monitor (15) is switched from the n-th frame to the (n+1)-th frame. Next, by comparing the frame number of the video signal (17A) currently being read and the frame number of the video signal (17B) being played back, the number of track jumps for reading the (n+2)th frame is calculated and the pickup (13) is performed. Make the truck jump. Then, the video signal (17^) is (n
+2) In synchronization with the image scanning start point of the th frame, switch (16) is switched from b to a, and in synchronization with the image scanning start point of the (n+3)th frame, the switch (16
A) Return from a to b.

This allows the frame memory (18B) to be added to the monitor (15).
This means that the signal of the (n+2)th frame is taken into the frame memory (18A) while outputting the image of the (n+1)th frame stored in the frame memory (18A). Afterwards, you can perform slow motion playback by following the same procedure.

At this time, by selecting the switching time t of the output image of the monitor (15), the speed of slow motion can be made variable, and the timing of switching the output image of the monitor (15) can be determined not by the time t but by an external signal. By giving this, frame-by-frame playback can be performed. Roughly speaking, reverse slow motion and reverse frame-by-frame playback can be performed by making the pickup (13) jump in the direction in which the frame number decreases.

FIG. 7 is a flowchart showing a method for performing double speed playback using the apparatus having the configuration shown in FIG. The video signal (17B) that was being played when the instruction for double speed playback was received from the outside was (n
−1) When the frame is the frame memory (
The video signal (17A) captured in frame 18A) is the n-th frame. The video signal (17A) is synchronized with the (n+1)th frame image scanning start point, and the switch (1
6^) Switch from a to b.

Then, the number of track jumps is determined from the frame number of the video signal @(17^) currently being read and the frame number (n+m) to be captured next into the frame memory (18B), and the pickup (13) is caused to track jump. The switch (168) is switched from b to C in synchronization with the image scanning start point of the (n+m)th frame using the video signal (17A), and the switch (168) is switched in synchronization with the image scanning start point of the (n4m+1)th frame. ^) from C back to b. As a result, the signal of the (n+m)th frame is taken into the frame memory (18B) while outputting the nth frame stored in the frame memory (18A) to the monitor (15). Next, by switching the switch (16B) from a to b in synchronization with the image scanning start point of the video signal (17B) being played back on the monitor (15), the output image of the monitor is changed from the nth frame to ( n+
m) Switch to frame number.

Thereafter, the number of track jumps is determined from the frame number of the video signal being read and the number @(n+m) of the next frame to be taken into the frame memory (18A), and the pickup (13) is caused to track jump. Then, in the video signal (17A), the switch (16^) is switched from b to a in synchronization with the image scanning start point of the (n+2m)th frame, and the switch (16^) is switched in synchronization with the image scanning start point of (n+2m+1). ^) from a to b, the frame memory (1BB) is transferred to the monitor (15).
) while outputting the image of the (n+m)th frame stored in the frame memory (188), the signal of the (n+2m)th frame is taken into the frame memory (188). And video signal (17B)
By switching the switch (1613) from b to a in synchronization with the image scanning start point of (
Switch from the n+m)th frame to the (n+2m)th frame. By continuing the same procedure thereafter, playback can be performed at approximately (m-2) times the speed in a pseudo manner, although there are some differences depending on the access time of the player. Furthermore, if m is set to a negative value, double-speed reproduction in reverse can be achieved.

In this way, special playback of CLV video discs is possible in the above-described embodiment as well as in the previous embodiment. Roughly speaking, in this embodiment, when playing an image,
Since the video signal is stored in the -H frame memory before processing, it is also possible to eliminate jitter caused by uneven rotation of the disk.

[Other Embodiments of the Invention] FIG. 8 is a block diagram showing a schematic configuration of main parts of an apparatus according to still another embodiment of the present invention. The signal recorded on the video disc (21) is read by the pickup (22), and after being processed by the signal processing section (23), the switch (
24) and into a frame memory (25), and then displays the image on a monitor (26).

In this way, by capturing the signal into the -H frame memory and then displaying the image on the monitor, CAV
, CLV When playing either disc, it is possible to remove jitter caused by uneven rotation or eccentricity of the video disc (21), so it is possible to play back images without synchronization or color unevenness caused by jitter. can.

Also, if you want to jump to a distant track rather than an adjacent track during playback, after receiving a track jump command, synchronize with the next image scanning start point, open the switch (24), and jump to the pickup (22). By continuing to send the signal captured in the frame memory (25) to the monitor (26) until the next signal to be played is retrieved after the track jump, the output image of the monitor (26) can be changed when the track jumps to a distant location. There is no interruption. Roughly, I replaced the video disc (21),
Also, when flipping the video disc (21) over and trying to play back the signals recorded on the opposite side, as described above, the image signals are captured into the frame memory (25) until the next image signal to be played is retrieved. monitor the signal (26
), the output image on the monitor (26) will not be interrupted even when the video disk (21) is replaced or turned over.

It should be noted that the present invention is not limited to each of the embodiments described above. For example, in each of the embodiments described above, each frame memory is for two frames, but it goes without saying that the present invention can be similarly applied even if the frame memory is for three or more frames. .

Furthermore, structural issues such as whether to provide the frame memory in the player section or the monitor section can be determined according to the specifications.

In short, the present invention can be implemented in various modifications without departing from its gist.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing a schematic configuration of main parts of an apparatus according to an embodiment of the present invention, FIG. 2 is a diagram illustrating a method for still image playback in the apparatus according to the embodiment, and FIG. 3 is a diagram showing slow motion reproduction in the apparatus according to the embodiment. FIG. 4 is a diagram showing a method for performing double-speed playback in an embodiment device, FIG. 5 is a block diagram showing a schematic configuration of main parts of another embodiment device of the present invention, and FIG. FIG. 7 is a diagram showing a method for performing slow-motion reproduction in the same embodiment apparatus, FIG. 7 is a diagram showing a method for double-speed reproduction in the same embodiment apparatus, and FIG. 8 is a diagram showing still another embodiment. DESCRIPTION OF SYMBOLS 1...Video disk, 2...-Motor 3...Pickup, 4...Signal processing part 5...Monitor,
6...Switch 7...Video signal, 8
... Frame memory representative patent attorney Kensuke Norichika (1 person) Figure 1 Figure 4 Figure 5 Figure 8 Hand, reading correction evening (self-motivated) 196σ7. Evening 58

Claims (1)

[Claims] (1) A video disc playback device consisting of a video disc player and a monitor that outputs the output signal of the video disc player as an image, which is equipped with a frame memory, and the output signal from the video disc player is temporarily stored in the frame memory. A video disc playback device characterized in that the output signal from the frame memory is supplied to the monitor after being stored.