KR0183170B1 - Reproducing method for the slow-motion picture of digital vcr - Google Patents

Abstract

1. FIELD OF THE INVENTION The invention as described in the claims: Slow regeneration method of BEAL.

2. Technical problem to be solved by the present invention: To provide a slow playback in units of frames when playing a recording medium in which one frame of data is recorded in a plurality of tracks in a slow mode.

3. Summary of the Invention Solution: The capstan motor is controlled by forward and reverse rotation so that slow playback in units of frames is performed.

4. Significant Use of the Invention: Used for slow regeneration of Besal

Description

Slow Playback Method of Digital BC

1 and 2 are diagrams for explaining the conventional slow play.

3 to 6 are views related to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of reproducing a digital signal (hereinafter referred to as a VCR), and more particularly, to a method of slow playback on a frame-by-frame basis when a recording medium having one frame of data recorded on a plurality of tracks is played in slow mode. will be.

Conventional VCR implements slow playback by slowing down the running speed of the tape by reducing the speed of the capstan motor when the video is played back in the slow mode. For example, when a VCR having an opposing head at an angle of 180 degrees as shown in the drawing of FIG. 1 performs slow playback at 1/2 times the trajectory of the head, the trajectory of the head is taken twice in the same track as in FIG. Leave the result of the injection. In this case, due to the azimuth loss effect, when the (+) azimuth track is scanned by the (-) azimuth head, almost no playback signal is generated, so only when the azimus on the track and the azimus on the head are the same. At that time, the data is detected with the value output from the head. Therefore, in such a case, an error in the playback signal increases in slow playback than in the normal playback, which causes a problem of deterioration in image quality.

In addition, in the case of ultra low speed reproduction such as 1 / 30x speed reproduction, the capstan motor speed should travel at ultra low speed 1 / 30x speed than the normal playback speed. The picture quality is further deteriorated.

Therefore, in the conventional slow play, since the same track is repeatedly scanned, there is a problem in that slow play in frame units cannot be fundamentally performed.

Accordingly, an object of the present invention is to provide a method that can solve the above-mentioned conventional problems.

Another object of the present invention is to provide an apparatus and a method for performing slow playback on a frame-by-frame basis when playing a recording medium having one frame of data recorded on a plurality of tracks in a slow mode.

In accordance with the present invention for achieving the above object, a slow playback method of BSR capable of reproducing a slow image slower than normal playback by driving a recording medium consisting of a plurality of tracks in one frame includes: After the normal playback and storage in the memory, the recording medium is reversed by a predetermined length so that a plurality of frame sections are stopped, and the data stored in the memory is continuously displayed during the stopped section, and the next frame should be read. After stabilizing the slow operation by restarting the recording medium at a point earlier than the predetermined interval, the data of the next frame is stored in the memory, and the operation is continuously repeated.

Hereinafter, a preferred embodiment of the present invention will be described with the accompanying drawings. In the following description, the detailed items for such methods are described in detail in order to provide a more thorough understanding of the present invention. However, it will be apparent to those skilled in the art that the present invention may be practiced without these specific details. In addition, features and well-known circuit configurations for the basic blocks of well-known VCR circuits are not described in detail in order not to obscure the present invention.

First, the basic principle of the present invention is to control the capstan motor forward and reverse rotation so that slow playback of the frame unit is performed. In slow mode, a tape, which is a recording medium, is driven forward by a capstan motor at a speed of normal playback (normal playback or normal play operation) to reproduce one frame of data once. The data of one frame reproduced in this way is stored in the memory. Image data stored in the memory is displayed on the monitor at the specified slow speed. While a frame of data is displayed, the Capstan motor is reversed to reverse the tape. When the tape is retracted by the set point, the capstan motor is stopped and the tape stops running. Just before all the data of one frame is displayed, the capstan motor rotates forward to drive the tape forward. After driving starts, the display operation ends and the next frame data currently displayed is newly stored in the memory. The operation after storage is the same as the above operation. This operation is repeatedly performed to implement slow playback in units of frames as a ratio.

3 shows the configuration of a circuit block of a VCR required for reproduction in accordance with the present invention. 4 shows the format of the magnetic tape used as the recording medium. For example, in the present invention, the format of the tape to be slow-played is composed of ITI (Insert Track Information), Audio, Video, and Subcode as shown in FIG. Assuming that one frame of data is compressed and recorded, an embodiment of the configuration and slow playback operation will be described below with reference to FIG.

Referring to FIG. 3, the PB AMP equalizer 2 performs waveform equalization after amplifying a signal reproduced from the PB head. The signal output from the equalizer 2 is provided to the PLL and the data detector 4, processed, and then output as digital data and clock. The ECC 6 receives the data, corrects an error, and stores one frame of data in the frame memory 14. The stored data is read back and provided to the data decompressor 8 to decompress the data. Digital to analog converter 10 provides the decompressed data to monitor 12 after D / A conversion. Therefore, an image signal is displayed on the screen. The microcomputer 20 controls the head drum and the capstan motor to control the running of the tape and the scanning of the head. When performing this control, a frame signal for dividing one frame is required, which is received from an ECC block that collects one frame data, and the microcomputer 20 reproduces one frame accordingly so that the data can be transferred to the ECC. In the microcomputer 20, it is possible to synchronize the frame signal output from the ECC and the track scanned by the actual head only after determining whether the current reproduced signal is the signal reproduced on which track within a frame. This information exists in the form of a track pair number among the data ID codes of audio and video in the tape format of FIG. 4, which is extracted from the ECC and transmitted to the microcomputer 20 through the line L1. The microcomputer 20 receives the track pair number, and if the track pair number of the immediately preceding track is 0 and the current track pair number is 0 again, determines the track as track number 1, and the previous track pair signal was 0 and the current track pair number. If 1, the track number is determined as 2. In this way, the track number is estimated to control forward, reverse and stop of the capstan motor.

The output form of data during normal reproduction and the operation of the circuit block according to the present invention in this case are as follows.

5 is a diagram showing a relationship between a frame reference signal in a steady state and a track actually scanned by the head. The capstan servo control performed by the microcomputer 20 of FIG. 3 may obtain the 5B signal of FIG. 5 that determines the track number to be scanned at present by dividing it 10 times based on the frame signal frp applied through the line L2. By comparing this with the track number estimated from the track pair number included in the ID actually read from the track, if the track currently being read is behind the track to be read, the tape speed is increased and if it is ahead, the control is performed in such a manner as to control the track number. As can be seen from Figs. 5A and 5B, a track scan of frp and the head corresponding thereto can be obtained. At this time, the read data are stored in the memory of ECC 6 and error corrected. In this process, one frame is delayed and transferred to the data decompressor 8 in the form of 5D of FIG.

Hereinafter, with reference to Fig. 6, the operation during slow playback will be described. 6 shows waveforms appearing at slow reproduction at 1/2 times speed. As can be seen from FIG. 6, the waveform 6B of the track number signal to be scanned can be grasped from the servo reference signal synchronized with the frame reference signal frp. In the case of 1 / 2x reproduction, first, in a section a of the 6A signal of FIG. 6, data of one frame is reproduced and error corrected by ECC, and then transferred to the data decompressor 8 to expand the data and display the result. At this time, since one frame is delayed, the data of the reproduced frame 1 is transferred to the data extension unit in the section (b). Since it is 1 / 2x playback, the data stored in ECC memory, that is, the data in Frame 1, is continuously transmitted to the next frame. On the other hand, in the section b, the servo control system prepares to read the next frame 2. In fact, even if only 10 consecutive tracks are read and stopped in order to play one frame on the track, the tape advances slightly more than the end of one frame due to the moment of inertia of the motor. Moreover, even if the motor starts to read and starts reading from the point where it stopped again, it takes time to stabilize. Therefore, in the present invention, to solve this problem, the tape is reversed slightly, that is, it returns to the section of the previous frame (section 6C waveform r in FIG. 6) and a little before the moment when the next frame must be read again (6C waveform in FIG. 6). Section f) Starting normal driving, the data of the next frame is read by normal reproduction from the start time of the next frame (rising edge of section c of 6A waveform in FIG. 6), and the data is transferred to the ECC block. As a result, in normal playback, 1/2 slow playback is performed because data of one frame is displayed twice at the time when two frames of data should be played back.

There are two tasks for performing the operation of the present invention as described above.

First of all, when reversing the tape, it is a matter of how much the tape actually reversed so as to retract only a certain length. This was solved by counting the number of capstan FGs in reverse in the present invention. In other words, the tape movement is actually obtained by multiplying the movement angle of the capstan motor by the radius of the pinch roller, so the movement angle of the capstan motor is proportional to the number of FG and the radius of the pinch roller is mechanically constant. By counting the number of movements of the tape, you can find out the movement of the tape.

Secondly, when the tape is advanced at the point f of the 6C waveform in FIG. 6, the data of the beginning of the next frame is reproduced exactly at the rising edge of the interval c. This is implemented by comparing the track number estimated from the track pair number with the track balance like the waveform of FIG. 6B in FIG. This makes it possible to control the speed of the capstan motor to synchronize the tracks that the track lift command actually scans.

On the other hand, in the case of the reproduction at a lower speed than the 1 / 2-speed reproduction, the head scans one frame and stops one frame, instead of scanning one frame, and more frames are applied to the principle of the present invention. If you stop it accordingly (2 frames stop for 1 / 3x speed, 3 frames stop for 1 / 4x speed, etc.), you can easily implement the application.

In the description of the present invention, the frame signal is provided in the ECC block, but is not limited thereto, and can also be obtained in the D / A converter. Similarly, the part generating the track pair signal can also be obtained from other parts than the ECC.

According to the present invention as described above, there is an effect that slow playback in units of frames can be performed when the recording medium having one frame of data recorded thereon is recorded in a plurality of tracks in the slow mode.

Claims (3)

In the slow playback method of BCAL, which is capable of playing a slow video slower than normal playback by driving a recording medium having a plurality of tracks of one frame: recording one frame of data normally and storing the same in a memory. The media is retracted by a preset length so that a plurality of frame sections are stopped, and the data stored in the memory is continuously displayed during the stopped section, and the driving starts at a point ahead of the point where the next frame should be read. After stabilization, storing the next frame of data in the memory and repeating the operation continuously. 2. A method according to claim 1, wherein the determination of the amount of reversing the recording medium by a predetermined length is performed by counting the number of pulses of the frequency generating signal provided from the capstan motor. 3. The method of claim 2, wherein aligning the start of the next frame is implemented by extracting a track number and synchronizing the frame signal with a track lift signal divided by the number of tracks constituting the frame. .