JPH089327A - Optical disk and its reproduction method - Google Patents

Abstract

PURPOSE:To increase the speed for special reproduction and to reduce a memory capacity of a reproduction circuit by arranging data in a GOP being video image information blocks in the lump for I-picture and P-picture each. CONSTITUTION:An analog video signal is fed to an A/D converter 30, in which the signal is converted into digital data. Then a motion vector is detected and compressed in a 3-dimensional direction and subjected to discrete cosine transformation by a discrete cosine transformation device 32 and the result is given to an adaptive quantization device 33, in which quantization and variable length coding are conducted. The compressed digital moving image information obtained in this way is formatted as a signal to be recorded on an optical disk by a buffer memory 38 and a format encoder 39. In this case accurate scene change is discriminated by a scene change discrimination device 42. An output from the discrimination device 42 is recorded in video attribute data as the representation of presence/absence of a scene change. Special reproduction or the like is attained by this format.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc and a method for reproducing the optical disc.

[0002]

2. Description of the Related Art FIG. 13 is a block circuit diagram of a conventional optical disk recording / reproducing apparatus disclosed in Japanese Patent Application Laid-Open No. 4-114369. Reference numeral 1 denotes an A / A for converting a video signal, an audio signal or the like into digital information. D converter, 2 is information compression means, 3 is frame sector conversion means for converting the compression information into sector information equal to an integral multiple of a frame period, 4
Is an encoder, 5 is a modulator for converting into a predetermined modulation code in order to reduce inter-code interference in the recording medium, 6 is a laser drive circuit for modulating laser light according to the modulation code, and 7 is a laser output switch. Is.

Further, 8 is an optical head for emitting the laser beam, 9 is an actuator for tracking the light beam emitted from the optical head 8, 10 is a traverse motor for sending the optical head 8, and 11 is Optical disc 1
A disk motor for rotating the motor 2, a motor drive circuit 19 and a motor control circuit 20. Further, 13 is a reproduction amplifier for amplifying the reproduction signal from the optical head 8,
Reference numeral 14 is a demodulator for obtaining data from the recorded modulated signal, 15 is a decoder, 16 is a frame sector inverse transforming means, 17 is information decompressing means for decompressing the compressed information, and 18 is decompressed information. For example, it is a D / A converter for converting into an analog video signal or an audio signal.

FIG. 14 shows the Moving P which is being standardized in order to compress, transmit and store digital moving image information.
icturecoding Experts Group (hereinafter "MPEG")
Is a simplified representation of the data array structure (layer structure). In the figure, reference numeral 21 denotes a Group of Picture (hereinafter, “GO
P ”), 22 is a GOP layer composed of several pictures (screens), 23 is a slice obtained by dividing one screen into several blocks, 24 is a slice layer composed of several macroblocks, 25 Is a microblock layer, and 26 is a block layer composed of 8 pixels × 8 pixels.

In the MPEG system, for example, the microblock layer 25 has a minimum coding unit of 8 × 8.
This block is composed of pixels, and this block is a discrete cosine transform (hereinafter referred to as "DC
"T"). At this time, adjacent 4
One Y signal block, one Cb block positionally corresponding to these Y signal blocks, and one Cr block, totaling six blocks, are called macroblocks. A slice is formed by collecting a plurality of these macroblocks. A macroblock is the minimum unit of motion compensation prediction, and a motion vector for motion compensation prediction is performed in macroblock units.

FIG. 15 is a diagram showing a coding structure when 17 screens are set to 1 GOP. In the figure, 27 is an I-picture which is video information for performing intra-frame DCT, and 28 is motion compensation in the forward direction. B which is video information by DCT encoding
-picture, 29 is the above I-pictu, which is located before and after in time
This is a P-picture on which DCT coding is performed with motion compensation using re and P-picture as reference screens. Also, FIG.
6 is a diagram showing a coding structure when 10 screens are 1 GOP, and FIG. 17 is a diagram showing a coding structure when 15 screens are 1 GOP.

Next, the conventional operation will be described with reference to the drawings.
As the compression technique of digital video information advances, the above-mentioned compression information is recorded on the optical disc, so that the conventional VTR
It is possible to realize a video filing apparatus which has excellent searchability and is extremely easy to use as compared with a tape medium represented by the above. Further, since such a disk file device handles digital information, there is no dubbing deterioration as compared with the case of recording an analog video signal, and since it is an optical recording / reproducing system, a non-contact and highly reliable system can be realized.

Conventionally, when recording such compressed moving image information on an optical disc, an optical disc recorder as shown in the block diagram of FIG.
Digitally compressed moving image information such as that of the EG system is recorded. At this time, the video information digitized by the A / D converter 1 is processed by the information compression means 2 into, for example, MP.
It is converted to a standard compressed moving image method such as the EG method. This compressed information is encoded and modulated to reduce the influence of intersymbol interference on the disc,
Recorded in. At this time, for example, the amount of data in each GOP unit is set to be approximately the same amount, and the GOP is divided into sectors equal to an integral multiple of the frame period to
It is clear that editing etc. is possible in units.

During reproduction, the optical disk 12
The video information recorded in is amplified by the reproduction amplifier 13,
After being restored to digital data by the demodulator 14 and the decoder 15, it is restored as pure video original data by removing the data such as address and parity by the frame sector inverse conversion means 16. Further, the information decompression means 17 reproduces it as a video signal by performing MPEG decoding, for example.
The / A converter 18 enables display on a monitor or the like.

As described above, when the MPEG method is used as the digital moving picture compression method, the method from the 15th to FIG.
As shown in Fig. 7, compression I-pic by intra-frame DCT
ture 27, B-picture 28 which is video information by DCT encoding for motion compensation in the forward direction, and DCT encoding for motion compensation using the I-picture and P-picture, which are temporally preceding and following, as reference screens. P-pic
The ture 29 records the combined encoding structure in the disc as it is.

At this time, the I-picture is D in the frame.
Since CT is used, it is possible to perform image reproduction by using this information alone. However, since P-picture performs motion compensation in the forward direction, image reproduction must be performed after the I-picture is reproduced. I can't do it. The B-picture is a prediction screen from both directions, so the above-mentioned I-pictu
It has a feature that it cannot be reproduced until after the re or P-picture is reproduced. In this case, the B-picture, which is bidirectionally predicted, naturally has the smallest data amount and the coding efficiency is good.

However, since this B-picture cannot be reproduced independently, an I-picture and a P-picture are required, but if the number of B-pictures is increased by that much, the buffer memory amount in the processing circuit increases and the data input. There is a problem that the delay time from to video playback increases. However, in storage media typified by optical disks and the like, a coding method with good compression efficiency is desired for long-term recording,
Since the delay time of the above video playback does not matter so much,
The encoding method as shown in FIGS. 15 to 17 is suitable.

Next, when the data having such an encoding structure is recorded on the disc, how the image retrieval and the high speed reproduction are performed is as follows. FIG. 17
In the case of having the coding structure as shown in (1), high-speed reproduction is possible by reproducing in I-picture units. In this case, I-pictu
Immediately after playing re, a track jump is performed and the next,
Or access the previous GOP and play the I-picture there. By repeating such an operation, as shown in FIG.
In the case of 7, the high-speed feed reproduction and the backward reproduction in which the feed speed is limited to an integral multiple of 15 times speed and 10 times speed in FIG. 16 can be realized.

However, in the actual image retrieval, if it is too fast, it will be difficult for the human eye to recognize it, and in order to confirm almost an image scene, the above-mentioned high-speed retrieval of 10 times or more is appropriate. In the case of searching for a detailed video point after performing the scene search of, it is necessary to perform fast-forward and reverse playback at several times speed. Therefore, it is clear that a wide range of special reproduction from several tens of times to several times of speed is required for effective video retrieval. However, in practice, for example, in the case of using compressed data of the MPEG system, if a P-picture is reproduced in the coding structure of FIGS. 15 to 17, the B-picture up to that point is also reproduced as a result. In practice, it was difficult to realize 4 to 8 times speed.

[0015]

Since the conventional reproducing method is a method for reproducing the above-mentioned coding structure as it is on the disc, when performing special reproduction, the I-picture is reproduced.
It could only be played in units. Therefore, fast-forwarding or rewinding reproduction is possible only at a speed corresponding to the number of frames included in one GOP or an integral multiple thereof.

In the digital video recording format shown in the conventional example, I-picture and P-pictur are used.
Since the arrays of e and B-pictures are arranged in order on the time axis, the special reproduction method is limited to the following method.

Particularly, in the conventional system for recording a digital moving image, the most basic special reproduction method is a special reproduction method using the information recorded in the TOC area at the innermost circumference of the disc. . in this case,
According to the start address of the scene change recorded in the TOC area and the start address of the video file, the digital moving picture image of the I-picture stored at the above address is read and special reproduction is possible by sequentially reproducing it. .

The read operation of the optical disk in this case is as shown in FIG.
It is represented by the flowchart of FIG. This flowchart shows a case where special playback is performed based on the address of the scene start portion of the moving image information recorded in the TOC area at the innermost circumference of the disc. First, the TOC area is jumped to and the scene start address is jumped. After storing in the internal memory, while jumping to the address stored above,
The I-picture in the jumped GOP is reproduced, the screen is displayed, and the operation of moving to the next jump destination address is repeated.

However, in such a method, a large amount of search destination addresses must be stored in the TOC, and the TOC information must be rewritten each time it is recorded.

In addition, during the special reproduction, it is necessary to skip the data of the B-picture when trying to reproduce the P-picture, but actually, the I-picture, the B-picture, and the P-picture are required.
However, when the track jump is performed, it may not be possible to reproduce the P-picture without waiting for rotation.

The data amount of the I-picture coded by the intra-frame DCT is the same as that of other P-pictures and B-pictu.
Since it is larger than re, it has a problem that it cannot be realized because the data input time is insufficient to perform ultra-high speed reproduction of several tens of times.

When a desired GOP is searched from an arbitrary position on the disk, several times are required to search the head position of each GOP (generally, the time code and address of video image are recorded). There was a problem that the search operation of was required.

Further, since the scene change position in the moving picture image information is not known, there is a problem that it is impossible to search for each scene.

[0024]

According to a first aspect of the present invention, a data array in a GOP, which is a video information block, is represented by an I-pictu.
Place them together for each re and P-picture, and during normal playback,
The video data of the I and P-pictures are read into the buffer memory, and after decoding, the B-pictures are sequentially decoded to restore the video data in the GOP.

According to the second aspect of the present invention, a recognition parity signal or header signal is recorded at the beginning of the I-picture.

According to a third aspect of the present invention, the data array in the video information block is divided into I-picture and P for each video information block.
-The data array of picture is replaced before and after.

According to a fourth aspect of the present invention, the data arrangement in the video information block is such that the I-picture and the P-picture are adjacent to each other and the I-picture and the P-picture are arranged for each video information block.
The data array of B-picture and the data array of B-picture are interchanged.

In a fifth aspect of the present invention, a pre-formatted portion in which address data is pre-formatted is arranged in front of each video information block and is arranged on a line in the radial direction of the disc.

According to a sixth aspect of the present invention, the next jump destination address for special reproduction is recorded in the attribute data recording area provided in front of each video information block.

According to a seventh aspect of the present invention, the presence or absence of a scene change detected from the temporal luminance and color information change of the video is recorded in the attribute data recording area provided in front of each video information block. .

According to an eighth aspect of the present invention, the optical disk is divided into a plurality of zones in which the scanning linear velocity of the light spot is constant for each radius range, and the address data and the header signal are pre-prepared at the beginning of each video information block. It is formatted, the number of data bits of each video information block is the same as each video information block, and the data bit length of the video information block of each sector is configured to be an integral multiple of the circumference of the track on the disc. is there.

According to a ninth aspect of the present invention, a mirror surface portion for detecting track offset is provided for each video information block unit.

According to a tenth aspect of the present invention, there is provided an optical head having a coarse actuator for accessing a predetermined position and a precision actuator for jumping to a predetermined track on the inner and outer circumferences of the disk during reproduction. Paragraph signal or header signal in the video information block of the optical disk described in any one of the items 1 to 9 is reproduced and the I-picture is reproduced, and then the track jump is performed to display the I-picture of the next video information block. By repeating the reproduction operation, high-speed fast-forward reproduction and reverse-forward reproduction are performed.

The invention of claim 11 is an optical head having a coarse actuator for accessing a predetermined position during reproduction and a precision actuator for jumping to a predetermined track on the inner and outer circumferences of the disk. Paragraph signal or header signal in the video information block of the optical disc according to any one of items 1 to 9 is searched and recognized to reproduce an I-picture, and then a plurality of P-pictures are continuously reproduced, and a track jump is performed. Then, the I-picture of the next video information block is reproduced, and then the operation of continuously reproducing the P-picture is repeated to perform high-speed fast-forward reproduction and reverse-forward reproduction.

According to the twelfth aspect of the present invention, the number of rotations of the optical disc is set to be higher during fast-forwarding or reverse-forwarding reproduction of the moving image than during normal reproduction.

According to the thirteenth aspect of the present invention, at the time of fast-forwarding or reverse-forwarding reproduction of a moving image, the number of rotations of the optical disc is increased in a data area that does not need to be read, and I-picyure data and P
-In the picture data area, the data is read by reducing the rotation to the linear velocity at which reproduction is possible.

[0037]

According to the first aspect of the invention, the data array in the GOP, which is a video information block, is set to I-picture and P-picture.
The video data of the I and P-pictures are read into the buffer memory during normal reproduction, and after decoding, the B-pictures are sequentially decoded to restore the video data in the GOP. Since it was done, Bp during special playback
Track jump can be done in the icture part.

According to the second aspect of the present invention, since the recognition parity signal or header signal is recorded at the beginning of the I-picture, position detection of the I-picture or P-picture during special reproduction and I-picture are performed. It is easy to determine whether it is a P-picture.

According to the third aspect of the invention, the data array in the video information block is I-pictu for each video information block.
Since the data array of re and P-picture has been replaced before and after,
Without interruption between consecutive GOPs during special playback, I
-The picture can be played continuously.

According to the fourth aspect of the invention, the data arrangement in the video information block is such that the I-picture and the P-picture are adjacent to each other, and the I-picture and the P-picture are arranged for each video information block.
-Because the front and rear of the data array of -picture and B-picture are interchanged, I-pictures during special playback can be continuously performed.

According to the invention of claim 5, the pre-formatted portion in which the address data is pre-formatted is arranged in front of each video information block on one line in the radial direction of the disc, so that the light spot is at an arbitrary position. Even when tracing is performed, the GOP head position can always be recognized, whereby the track jump start point can be defined.

According to the invention of claim 6, the next jump destination address for special reproduction is recorded in the attribute data recording area provided in front of each video information block.
By repeating the track jump based on the above information at the time of special reproduction, for example, special reproduction completed in a moving image scene or continuous reproduction only at the beginning of the scene becomes possible.

According to the invention of claim 7, the presence or absence of a scene change detected from the temporal luminance and color information change of the video is recorded in the attribute data recording area provided in front of each video information block. , It is possible to play only the beginning of the scene during special playback, or to edit in scene units during editing.

According to the invention of claim 8, the optical disk is divided into a plurality of zones in which the scanning linear velocity of the light spot is constant for each radius range, and the address data and the header signal are provided at the head of each video information block. Pre-formatted, the number of data bits of each video information block is the same as each video information block, and the data bit length of the video information block of each sector is configured to be an integral multiple of the circumference of the track on the disk. Therefore, it is possible to suppress the variation of the linear density within a predetermined range and to recognize the GOP head position even when reproducing an arbitrary position.

According to the invention of claim 9, since the mirror surface portion for detecting the track offset is provided for each video information block, the head position of the GOP can be recognized by this mirror surface portion.

According to the tenth aspect of the invention, an optical head having a coarse actuator for accessing a predetermined position and a precision actuator for jumping to a predetermined track on the inner and outer circumferences of the disk during reproduction is claimed. The parity signal or the header signal in the video information block of the optical disc according to any one of items 1 to 9 is searched and recognized to reproduce the I-picture, and then the track jump is performed, and the I-picture of the next video information block is reproduced. High-speed fast-forward playback and fast-forward playback are performed by repeating the picture playback operation. Therefore, by repeating the track jump based on the parity or header signal provided at the beginning of the I-picture, each GOP unit I-pictu
Replay can be performed.

According to the invention of claim 11, an optical head having a coarse actuator for accessing a predetermined position and a precision actuator for jumping to a predetermined track on the inner and outer circumferences of the disk during reproduction is claimed. The parity signal or the header signal in the video information block of the optical disc according to any one of items 1 to 9 is searched and recognized to reproduce an I-picture, and then a plurality of P-pictures are continuously reproduced, and a track is further recorded. Since the I-picture of the next video information block is jumped to be reproduced and the P-picture is continuously reproduced next, high-speed fast-forward reproduction and reverse-forward reproduction are performed, so that the reproduction speed is improved. .

According to the twelfth aspect of the invention, the speed of rotation of the optical disk is set to be higher than that during normal data reproduction during fast-forwarding or reverse-forwarding reproduction of a moving image, so that the data transfer rate is improved.

According to the thirteenth aspect of the present invention, at the time of fast-forwarding or reverse-forwarding reproduction of a moving image, the number of rotations of the optical disk is increased in the data area which does not need to be read, and the I-picyure data and P-picture data area can be reproduced. Since the rotation is reduced to the linear velocity to read the data, the overall playback speed is improved.

[0050]

【Example】

Example 1. 1 is a block circuit diagram showing a recording system of an optical disk device according to a first embodiment of the present invention. In the figure, 30
Is A for converting analog video signals to digital
/ D converter, 31 is a motion detector for detecting a motion vector of a digital video signal, 32 is a discrete cosine converter for decomposing video information into frequency components, 33 is an adaptive quantizer, and 34 is an inverse quantum. , 35 is an inverse discrete cosine converter for restoring the original video information from frequency components, 36 is a frame memory, 37 is a variable length encoder, 3
8 is a buffer memory, 39 is a format encoder for adding address information and attribute data, 40 is a color information comparator for comparing the color information before and after the screen, especially in the reference screen after motion compensation by motion vector detection. , Which compares the color components before and after the screen that are temporally displaced. Reference numeral 41 is a brightness information comparator for comparing the brightness information before and after the screen, and 42 is a scene change judging device for judging the presence or absence of a scene change based on the outputs of both comparators 40, 41. The detector 100 is configured. 43 is a modulation circuit for reducing the influence of intersymbol interference, 44 is a laser modulation circuit for modulating the laser based on information from the modulation circuit, 45 is a servo circuit in the optical disk device, and 46 is a system controller.

FIG. 2 is a diagram showing a recording format of digital moving image data in the first embodiment. Figure 2
In (a), 47 is a wobble pit of a sample servo format or a mirror surface portion for track offset correction in a continuous guide groove system, 48 is a zone address indicating a current zone in a disk of a zone angular velocity constant rotation (CAV) system, and 49 is a video GOP. Header and video GOP address indicating the address of GOP, 50 is video attribute data for recording attribute data of the video signal, and 51 is I-pic indicating the beginning of the I-picture
ture header, 52 is a video header composed of 49 to 51, 53 is I-picture data, 54 is second I-picture data divided by a servo pit or a mirror surface, 5
5 is the third I-picture data divided similarly to 54,
56 is a P-picture header, and 57 and 58 are P1-picture data divided similarly to 54.

Further, FIG. 2B shows video attribute data 50.
FIG. 5 is a diagram showing a detailed format structure recorded in
9 is a scalability mode (type of hierarchical structure) of the digital video data array, 60 is the number of frames in the GOP, 61 is a GOP internal structure that defines the array of I / B / P-pictures in the GOP, and 62 is an I- Data array structure / position in picture, 63 is detailed attribute data such as whether the video in GOP is pan, zoom, or includes scene change, 64 is one video area formed from a plurality of GOPs A time code, 65 is a jump destination address during special playback, 66 is a voice mode, 67 is a still image mode,
68 is a reserve area, 47 is a wolve pit / mirror surface,
It corresponds to the wall pit pre-formatted on the optical disk shown in FIG. 12 or the mirror surface portion provided in the continuous guide groove shown in FIG.

FIG. 3 is a diagram showing changes in the disc rotation speed when the video data recorded in the format shown in FIG. 2 is reproduced at a high speed by increasing the disc rotation speed.

FIG. 4 is a flow chart in the case of performing special reproduction based on the jump destination address at the time of special reproduction written in the video attribute data area of the head portion of the video GOP.

FIG. 5 is a flow chart in the case of performing special reproduction based on the data recorded in the video attribute data of the head portion of the video GOP indicating the presence or absence of a scene change.

FIG. 6 shows I-picture and P-picture in GOP.
It is a flow chart in the case of performing special reproduction such that only one is continuously reproduced.

Next, the operation of the first embodiment will be described with reference to the drawings. For example, a video signal represented by MPEG is subjected to digital video encoding processing as shown in FIG. 1 and recorded on a disc. At this time, first, the analog video signal is converted into digital data by the A / D converter 30, the motion vector is detected by the motion vector detector 31, and the analog video signal is compressed in the three-dimensional direction compared with the reference image. The discrete cosine transformer 32 discretizes in the frequency direction (two-dimensional direction), and the adaptive quantizer 33 performs quantization and variable length coding.

The compressed digital moving image information thus obtained is added with an address, a header, attribute data and the like by the buffer memory 38 and the format encoder 39, and is formatted as a signal to be recorded on the optical disc. At this time, the frame memory 36, which is connected to the output of the inverse discrete cosine converter 35, judges the scene change by comparing the front and back of the frame memory 36 and detecting the abrupt image change by the motion vector detector 31. Is possible.

In this case, in particular, based on the results of the color information comparator 40 and the brightness information comparator 41, the color information and the brightness information are separately compared in the time axis direction, and the change amount and the change in each screen unit. By comparing the speeds and the like, the scene change determiner 42 can accurately determine the scene change.

The output from the scene change determiner 42 is stored in the video attribute data 50 of FIG. 2 as the presence / absence of a scene change. In addition, in the format of FIG. 2A, the video attribute data 50 includes the presence / absence of a scene change, the jump destination address at the time of special reproduction, the structure in the GOP, the number of pictures in the GOP, the scalability mode, the time code, etc. Can be written, so that special reproduction or the like based on these attribute data is possible.

FIG. 2 is a diagram showing a digital moving image video data recording format for that purpose, which is I-picture and P-pic.
ture is adjacent and the video attribute data 50 is G
It is placed at the beginning of the OP. At the time of recording, the presence / absence of a scene change is stored in the video attribute data 50 in FIG. 2 based on the determination result of the scene change determiner 42 in the digital moving image video recording circuit shown in FIG. Remember the address. At this time, since the buffer memory 38 exists in the digital moving image video recording circuit, the recorded data is still held in the buffer memory 38 during the next video processing, so that the jump destination address can be stored.

For example, if the next GOP is an image that does not require jump reproduction (for example, if it is a sequence of fast-moving images, a still image similar to the previous GOP), the next GOP is It is stored in the attribute data that there is no need to perform interlaced reproduction, and when the next GOP needs to be reproduced, a flag indicating that it is necessary is set to sequentially reproduce only this video attribute data 50, and it is necessary to reproduce. Only when a certain flag is set, special playback can be performed by repeating the operation of playing back the next GOP for which the flag is set.

In this case, the jump destination address may be directly specified instead of the flag. It is needless to say that in the case of reverse reproduction, even if the capacity of the buffer memory 38 is not large, it is possible to easily realize the storage of the jump destination address and the setting of the flag indicating the necessity of the reproduction of the previous GOP.

The read operation of the optical disk in this case is as shown in FIG.
The video attribute data 50 is read after detecting the address of the GOP destination and the I-picture of the GOP is reproduced if there is a thin change according to the presence or absence of a scene change. G
It is possible to continue special playback by jumping to OP.

Further, as shown in the flow chart of FIG.
The special reproduction can be performed by reading the jump destination address stored in the video attribute data 50. In this case, the jump destination address is stored by reading the video attribute data 50, the I-picture is reproduced based on this, and the special reproduction is performed by continuing the track jump.

By using such a method, a GO that is necessary among a plurality of GOPs formed on the disk is obtained.
Special reproduction such that only P is sequentially reproduced becomes possible. In these cases, still images are continuously displayed or still images at the beginning of the scene are continuously reproduced.

Further, during special reproduction such that I-picture and P-picture are continuously reproduced, it is represented as shown in the flowchart of FIG. At this time, the I-picture and P-picture are read after the video header is detected, the track jump is performed after the B-picture header is detected, and the same operation is repeated from the video header in the next GOP. However, in reality, since the amount of I-picture and P-picture data in one GOP is large, it is considered that the special reproduction ratio does not become so large by this method.

Example 2. Next, a second embodiment will be described with reference to the drawings. FIG. 7B is a diagram showing a data reading method when the video data recorded in the format of FIG. 2A is reproduced at high speed by performing a track jump, and FIG. 7B is a video header 52. FIG. 7C is a diagram showing the arrangement of the portion on the disc, and FIG. 7C is a diagram showing the state of the track jump at the video header portion.

FIG. 8 shows that the arrangement of the I-picture and the P-picture is changed before and after for each GOP so that the I-picture can be reproduced at the time of a track jump with a minimum waiting for rotation. , 69 is an audio header indicating the beginning of the audio signal, 70 is audio data, 71 is video data recognition parity for recognizing the beginning of video data, and 72 is the second P-picture.
P2-picture header that indicates the beginning of the, 73 is P2-picture header
Data, 74 is a B-picture header indicating the beginning of the B-picture, 75 to 79 are B1-picture data, and 80 is an end mark indicating the end of GOP.

FIG. 9 shows I-picture, P-picture and B-pictu.
By replacing the video information arrangement with "re" in GOP units, I-picture playback during track jumps can be minimized by waiting for rotation.
1 to 88 are B-picture data.

Next, the operation of the second embodiment will be described with reference to the drawings. In FIG. 7A, the data array in the GOP is I-pic.
It is arranged in the order of ture, P-picture, and B-picture.
In this case, in order to perform special reproduction, for example, the video header 52 including the video GOP address 49 and the video attribute data 50 in FIG. 2 is read, the I-picture is reproduced, and then the P-picture and the B-picture are skipped. Next GO
Special playback is possible by repeating P I-picture playback.

However, in this case, I-p per GOP
Since the data occupancy rate of icture is two-dimensional compression, it is quite large. For example, it has a data amount of 3 to 5 screens of B-picture, so even if the playback of P-picture or B-picture is skipped, The special reproduction efficiency does not increase so much, and there is a problem that the special reproduction ratio cannot be increased even if the rotation waiting time occurs. However, if 1 GOP in FIG. 16 has 10 screens or 15 screens in FIG. 17, special reproduction at about double speed or triple speed is possible.

Therefore, in order to reduce the rotation waiting time, a data array as shown in FIG. 8 can be considered. The data arrangement in this case is to switch the order of I-picture and P-picture between adjacent GOPs. In the case of FIG. 8, after the I-picture in the first GOP has just been reproduced, a track jump is performed and immediately after that, or after a certain servo stabilization period, I-p in the next GOP.
The arrangement is such that the icture can be played.

Furthermore, as shown in FIG. 9, I-picture
By sequentially replacing the three, P-picture, and B-picture in GOP units, I-pictu is more than the case of FIG.
A method that allows continuous data input of re is considered.
In this case, since the I-pictures can be continuously read out among the three GOPs, in the GOP configuration of FIGS. 15 and 16, the I-pictures in the three GOPs are continuously played back, which is almost smooth special playback. Is possible.

As described above, since the I-picture data that can be independently reproduced in the GOP can be reproduced between the GOPs without waiting for rotation, the special reproduction by the smooth continuous moving image is different from the first embodiment. Is possible.

Example 3. FIG. 10 shows the format arrangement on the disk in the continuous guide groove system in the third embodiment of the present invention. Further, FIG. 11 shows the format arrangement on the disk in the sample servo system in the third embodiment. Further, FIG. 12 is a flowchart of a data read operation for increasing the rotation speed of the disc during special reproduction according to the third embodiment.

Next, the operation of the third embodiment will be described.
Generally, in order to increase the recording density of an optical disc, C
CLV recording (constant linear velocity recording) is desirable instead of AV recording (constant rotational speed recording). However, in this case, the beginning portion of the video data, the arrangement of I-pictures, etc. are not determined on the disk, and the arrangement of I-pictures, etc. becomes random, so that the operations of the first and second embodiments are difficult. Become. Therefore, the disk is divided into zones as shown in Fig. 10 and Fig. 11,
It is conceivable that the head areas of GOPs are aligned in the disk radial direction in each zone.

In this case, the linear recording density is made substantially constant between the zones by changing the number of rotations of the disk motor in each zone, or conversely, the number of motor rotations is constant and the data clock for recording and reproduction is changed. Therefore, the linear recording density between the zones can be made constant.

However, in this case, since the recording capacities per disk revolution are different between the zones, the zone division should be set so that the recording capacity per GOP is an integral multiple of the recording capacity per disk per revolution. Can be realized with. For example, 1 GOP = 5 tracks in the zone in the inner circumference area, while 1 GOP in the zone in the outer circumference area.
It is also possible to arrange it as OP = 2 tracks.

Further, if the zone division is set so that the data amount for one-half the disk is an integer multiple, the data amount will be finer, and will be an integer multiple of the data amount for one-fourth disk. By further setting the zones as described above, it is possible to perform finer zone division.

Further, in this case, the GOP address in the video information is written immediately after the servo pit (wobble pit) in the sample servo or the mirror surface portion in the continuous guide groove system, and the mirror surface portion or wobble pit in the portion where the GOP address is recorded. By arranging so that the length and the like are different from other portions, it is possible to use the sum signal (reflection signal) from the optical head as a reference for the search at the time of search.

Further, in the system for recording / reproducing a digital moving picture image using such an optical disc, in addition to the special reproduction system using the track jump shown in the above-mentioned first and second embodiments, the disc during continuous reproduction is also used. It is also possible to perform special reproduction by increasing the number of rotations. For example, if the disc rotation speed is doubled, the transfer rate doubles, but data reproduction is possible. At this time, for example, double speed reproduction is possible by reproducing only I-picture or P-picture. Become.

Further, if the disk rotation speed is increased by 4 times or 8 times, the data speed becomes too high, and actual data detection may become impossible. In this case, as shown in FIG. 3, during I-picture reproduction and P-picture reproduction, the disc rotation speed is reduced to a linear velocity at which reproduction is possible, and in the area where B-picture is recorded. Can also be realized by increasing the disk rotation speed.

The drive operation of the optical disc at this time is as follows.
As shown in the flowchart of FIG. 12, first, the number of rotations is increased by n times, and then the video header is detected and I-p is detected.
The operation of reading icutre data and jumping to the next GOP is repeated. In this case, I-p is added to the video attribute data 50.
By storing the arrangement of the icture, the acceleration area and deceleration area of the disk motor can be set.

[0085]

According to the invention of claim 1, one GOP is provided.
Since I-picture and P-picture in a unit are continuous,
By performing the track jump, only the I-picture can be continuously reproduced, and the reproduction time of the B-picture can be omitted, so that the special reproduction speed is improved. Also, I
Since the -picture and the P-picture are arranged adjacent to each other, the memory capacity of the reproducing circuit can be reduced.

According to the second aspect of the present invention, since the recognition parity signal or header signal is recorded at the head of the I-picture, the management data at the head of the GOP is not reproduced at the time of the track jump. Continuous playback can be performed.

According to the third aspect of the present invention, the data array in the video information block is I-pictu for each video information block.
Since the data array of re and P-picture has been replaced before and after,
When you repeat the track jump and perform special playback, B
-Since the playback time of the picture can be omitted and the rotation waiting time can be omitted, high-speed and smooth video image playback can be performed.

According to the fourth aspect of the present invention, the data arrangement in the video information block is such that the I-picture and the P-picture are adjacent to each other, and the I-picture and the P-picture are arranged for each video information block.
-Since the front and rear of the data array of picture and B-picture have been swapped, the playback time of B-picture can be omitted and rotation waiting time can be omitted when performing special playback by repeating track jumps, so it is smooth at high speed. It is possible to play various video images.

According to the invention of claim 5, the pre-formatted part in which the address data is pre-formatted before each video information block is arranged on one line in the radial direction of the disc to arrange the I-picture. Since it is fixed on the disk, the GOP head position can always be recognized even when the light spot traces an arbitrary position, and thus the track jump start point can be defined.

According to the invention of claim 6, the next jump destination address for special reproduction is recorded in the attribute data recording area provided in front of each video information block.
Different special playback is possible depending on the content of the video image,
In addition, a special reproduction method can be designated at the time of recording.

According to the invention of claim 7, since the presence / absence of a scene change is recorded in the attribute data recording area provided in front of each video information block, only the still image immediately before or immediately before the scene change is sequentially reproduced. By doing so, an image search can be performed.

According to the present invention, the optical disk is divided into a plurality of zones in which the scanning linear velocity of the light spot is constant for each radius range, and the address data and the header signal are provided at the head of each video information block. Pre-formatted, the number of data bits of each video information block is the same as each video information block, and the data bit length of the video information block of each sector is configured to be an integral multiple of the circumference of the track on the disk. Therefore, the fluctuation of the linear density can be suppressed within a predetermined range, and the GOP head position can be recognized even when the arbitrary position is being reproduced.

According to the ninth aspect of the present invention, since the mirror surface portion for detecting the track offset is provided for each video information block, the length of the mirror surface portion or the like is changed so that the optical signal can be reproduced without reproducing the data. G from the sum signal only at the head
The start position of OP can be recognized.

According to the tenth aspect of the present invention, at the time of reproduction, the parity signal or the header signal in the video information block of the optical disk is searched and recognized to reproduce the I-picture, and then the track jump is performed, and the next video information block of the next video information block is reproduced. High-speed fast-forward reproduction and reverse-forward reproduction are performed by repeating the operation of reproducing the I-picture. Therefore, by repeating the track jump based on the parity or header signal provided at the beginning of the I-picture, I-picture reproduction can be performed in GOP units.

According to the invention of claim 11, at the time of reproduction, the parity signal or the header signal in the video information block of the optical disk is searched and recognized to reproduce the I-picture, and then a plurality of P-pictures are continuously reproduced. Further, the track jump is performed to reproduce the I-picture of the next video information block, and then P
-High-speed fast-forward playback and reverse-forward playback are performed by repeating the operation of continuously playing pictures, so the playback speed is improved.

According to the twelfth aspect of the invention, since the rotation speed of the optical disc is set higher during fast-forwarding or reverse-forwarding reproduction of the moving image than during normal data reproduction, the data transfer rate is improved.

According to the thirteenth aspect of the present invention, at the time of fast-forwarding or reverse-forwarding reproduction of a moving image, the number of revolutions of the optical disk is increased in the data area which does not need to be read, and the I-picyure data and P-picture data area can be reproduced. Since the data is read by reducing the rotation to the linear velocity, it is possible to perform high-speed special playback of smooth moving image without performing track jump.

[Brief description of drawings]

FIG. 1 is a block circuit diagram of a recording system according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a digital moving image video data recording format according to the first embodiment.

FIG. 3 is a diagram showing a change in disk rotation speed when video data of Example 1 is reproduced at high speed.

FIG. 4 is a flowchart for performing special reproduction based on a jump destination address written in the video attribute data according to the first exemplary embodiment.

FIG. 5 is a flowchart of the data reading operation of the optical disc at the time of special reproduction in the first embodiment.

FIG. 6 is a flowchart of an optical disk data reading operation during special reproduction in which the I-picture and P-picture are continuously reproduced according to the first embodiment.

FIG. 7 is a diagram showing a digital video data recording format according to a second embodiment of the present invention.

FIG. 8 is a diagram showing a digital video data recording format according to a second embodiment.

FIG. 9 is a diagram showing a digital video data recording format according to a third embodiment of the present invention.

FIG. 10 is a diagram showing a digital video data recording format on a disc of a continuous guide groove type according to a third embodiment.

FIG. 11 is a diagram showing a digital video data recording format on a disk of a sample servo system according to a third embodiment.

FIG. 12 is a flowchart of a data read operation for increasing the number of rotations of the disc during special reproduction according to the third embodiment.

FIG. 13 is a block circuit diagram of a conventional optical disc recording / reproducing apparatus.

FIG. 14 is a diagram showing an MPEG data array.

[Fig. 15] Fig. 15 is a diagram illustrating an encoding structure when 17 screens are 1 GOP.

[Fig. 16] Fig. 16 is a diagram illustrating an encoding structure when 10 screens are 1 GOP.

FIG. 17 is a diagram showing an encoding structure when 15 screens are set to 1 GOP.

FIG. 18 is a flow chart in the case of performing special reproduction based on an address in which a scene head portion of digital moving picture image information stored in a recording format of a conventional example is stored in a TOC area on the innermost circumference of the disc.

[Explanation of symbols]

30 A / D converter, 31 motion detector, 32 discrete cosine converter, 33 adaptive quantizer, 34 inverse quantizer,
35 inverse discrete cosine transformer, 36 frame memory,
37 variable length quantizer, 38 buffer memory, 39
Format encoder, 40 color information comparator, 41
Luminance information comparator, 42 Scene change determiner, 43
Modulation circuit, 44 Laser modulation circuit, 45 Servo circuit,
46 system controller, 47 wall pit / mirror surface section, 48 zone address, 49 video GOP address, 50 video attribute data, 51 I-picture header, 52 video header, 53, 54, 55 I-pictu
re data, 56 P-picture header, 57, 58 P1
-picture data, 59 scalability modes, 60
Number of frames, 61 GOP internal structure, 62 I-pictu
data array structure / position in re, 63 detailed attribute data,
64 time code, 65 jump destination address, 66
Audio mode, 67 still image mode, 68 reserved area, 69 audio header, 70 audio data,
71 Video data recognition parity, 72 P2-picture
Header, 73 P2-picture data, 74 B-picture
Header, 75 to 79 B-picture data, 80 end mark, 81 to 88 B-picture data, 100 Scene change detector.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Internal reference number FI Technical indication H04N 5/93 7/24 H04N 7/13 Z 9369-5D G11B 27/10 A

Claims (13)

[Claims] 1. Digital video information is DC in a frame
I-picture, which is video information for T, and P-picture, which is video information by DCT coding for motion compensation in the forward direction
And the above-mentioned I-picture and P-p located before and after in time.
It is a sequence of video information blocks of several to several tens of frame units in which a B-picture subjected to DCT coding in which motion compensation is performed is mixed using icture as a reference screen, and the video information blocks of this number to several tens of frames unit. Address data is pre-formatted before each, and the data array in each video information block is I-picture and P-pictu.
An optical disc that is placed together for each re. 2. The optical disk according to claim 1, wherein a recognition parity signal or header signal is recorded at the beginning of the I-picture. 3. A data array in a video information block, wherein the front and back of the data array of I-picture and P-picture are interchanged for each video information block. optical disk. 4. The data array in the video information block is I
-picture and P-picture are adjacent to each other, and I-picture, P-picture and B-picture for each video information block
The optical disc according to claim 1, wherein the front and rear sides of the data array are replaced. 5. Digital video information is DC in a frame
I-picture, which is video information for T, and P-picture, which is video information by DCT coding for motion compensation in the forward direction
And the above-mentioned I-picture and P-p located before and after in time.
In an optical disc device for recording information consisting of one video file unit in combination with a B-picture subjected to DCT coding with motion compensation using icture as a reference screen, it is pre-formatted before the video file unit. An optical disc in which address data is arranged on a line in the radial direction of the disc. 6. Digital video information is DC in a frame
I-picture, which is video information for T, and P-picture, which is video information by DCT coding for motion compensation in the forward direction
And the above-mentioned I-picture and P-p located before and after in time.
When special reproduction is performed in an attribute data recording area provided in front of the video file unit in a single video file unit in which a B-picture subjected to DCT coding with motion compensation using icture as a reference screen is combined. An optical disc in which a jump destination address next to is recorded. 7. Digital video information is DC in a frame
I-picture, which is video information for T, and P-picture, which is video information by DCT coding for motion compensation in the forward direction
And the above-mentioned I-picture and P-p located before and after in time.
In one video file unit in which a B-picture subjected to DCT coding in which motion compensation is performed using the icture as a reference screen is combined, the temporal data of the video is stored in an attribute data recording area provided in front of the video file unit. An optical disc on which the presence / absence of a scene change detected from changes in various brightness and color information is recorded. 8. The optical disc is divided into a plurality of zones in which the scanning linear velocity of the light spot is constant for each radius range, and the address data and the header signal are pre-formatted at the beginning of each video information block in advance. The number of data bits of each video information block is the same as that of each video information block, and the data recording bit length of the video information block of each sector is configured to be an integral multiple of the circumferential length of the track on the disk. An optical disc according to claim 1. 9. The optical disc according to claim 8, wherein a mirror surface portion for detecting track offset is provided for each video information block unit. 10. An optical head having a coarse actuator for accessing a predetermined position during reproduction and a precision actuator for jumping to a predetermined track on the inner and outer circumferences of the disk, as claimed in any one of claims 1 to 9. Of the optical disc described in any one of 1) to 1) search and recognize the parity signal or the header signal in the video information block, reproduce the I-picture, and then perform track jump, and repeat the operation of reproducing the I-picture of the next video information block. A method of reproducing an optical disc, which is capable of performing high-speed fast-forward reproduction and high-speed reverse reproduction. 11. An optical head having a coarse actuator for accessing a predetermined position during reproduction and a precision actuator for jumping to a predetermined track on the inner and outer circumferences of the disk, as claimed in any one of claims 1 to 9. Of the optical disc of any one of the above items, a parity signal or a header signal in the video information block is searched and recognized to reproduce an I-picture, and then a plurality of P-pictures are continuously reproduced, and a track jump is performed to further reproduce the next video information. A method for reproducing an optical disk, characterized in that high-speed fast-forward reproduction and reverse-forward reproduction are performed by repeating an operation of reproducing a block I-picture and then continuously reproducing a P-picture. 12. A reproducing method for an optical disc, wherein the number of rotations of the optical disc is set to be higher than that in normal data reproduction when the moving image is fast forwarded or reversely played back. 13. Fast-forwarding or reverse-forwarding reproduction of a moving image, the rotation speed of the optical disk is increased in a data area that does not need to be read, and the I-picyure data and P-picture data areas are rotated down to a reproducible linear velocity. A method for reproducing an optical disk, characterized in that data is read.