JP3093724B2 - Moving image data reproducing apparatus and reverse reproducing method of moving image data - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a moving picture data reproducing apparatus and a moving picture data reverse reproducing method, and more particularly to an MPEG (Moving Picture) recorded on a medium.
The present invention relates to a moving image data reproducing apparatus for reproducing a compressed and coded image based on the Experts Coding Group standard and a reverse reproducing method of moving image data.

[0002]

2. Description of the Related Art As one of high-efficiency coding methods for compressing data of a moving image signal, ISO / IEC11172 is used.
There is an MPEG system which is a standard established in the above.

[0003] This MPEG system uses DTC (Discr.
intra-picture encoding that removes spatial redundancy of an image using an éte Cosine Transform), and forward prediction encoding that removes temporal redundancy of an arbitrary picture and a preceding picture, Then, image data compression is performed using each technique of bidirectional predictive encoding for removing temporal redundancy of an arbitrary picture and pictures before and after it.

[0004] Video data (M
PEG data) is coded by intra-picture coding and forms one picture by itself, and one picture is coded by forward prediction coding to refer to the previous picture. And a B picture that is encoded by bidirectional prediction encoding and constitutes one image by referring to a previous image and a future image. The I picture and the P picture are collectively called a core picture. A GOP (Group Of Picture: DVD) that collects one or more pictures as a unit of MPEG data
For a maximum of 0.5 seconds).

Video CDs (Compact Disks) and DVDs are used as image reproducing devices using the MPEG system.
(Digital Video Disk) has been put to practical use.

However, in the above-mentioned video CDs and DVDs, M
In the special reproduction of PEG data, particularly in the case of reverse reproduction, since decoding is performed with reference to a past or future image as described above, a first reverse reproduction method in which compressed data is read and decoded repeatedly many times. Alternatively, there is only a second reverse reproduction method in which reproduced pictures are stored in a memory as frame data and sequentially displayed in the reverse order of the order in which the pictures were stored during reverse reproduction.

In the first reverse reproduction method, since the compressed data recorded as described above must be read, a seek operation or the like is involved, and the reproduction speed is reduced. In addition, the compressed data must be reproduced from the beginning of the read data, that is, in the direction opposite to the reproduction direction of the moving image.

In the second reverse reproduction method, reproduction can be performed without any problem in reproduction speed.
1 GOP (maximum data for 0.5 seconds on DVD, 720
× 480, 30 fields, 79M in 16-bit color
A large-capacity image (frame) memory for storing expanded image data (frame data) for a unit of (bit) is required.

Referring to FIG. 5, which shows a block diagram of a general conventional first moving image data reproducing apparatus which has only about 4 Mbits of image memory and thus uses the first reverse reproducing method, FIG. A moving image data reproducing apparatus includes a stream supply source that reproduces a medium and outputs a bit stream of read data, an MPEG decoder that decodes a bit stream of read data, and a decode controller that controls the entire decoding operation. 6 and an image memory 4 storing each picture data for display and decoding.

The image memory 4 includes a decode memory area for holding one past / future picture (holding picture) to be referred by the MPEG decoder 3 for decoding the target picture, and a display target picture decoded by the holding picture. And a display memory area for storing.

Next, with reference to FIG. 5, a description will be given of the operation of the first moving image data reverse reproducing method which is the reverse reproducing operation in the conventional first moving image data reproducing apparatus. The source 1 is a device that supplies a bit stream as compressed data, and corresponds to a DVD drive and a DVD decoder in a DVD player. During reverse playback, M
As in the first reverse playback method described above, the PEG decoder 3 performs GOP
The data is read from the beginning and decoded with reference to the held picture held in the decode memory area of the image memory 4. The decoded display target picture is stored in the image memory 4
In the display memory area.

1G of the first conventional moving picture data reproducing apparatus
OP has one I picture I1 and ten P pictures P1
Referring to FIG. 6, which shows an example of a decoding operation at the time of reverse reproduction of data consisting of .about.P10, as shown, in the reverse reproduction, pictures P10 must be reproduced from P10 to P1, I1 in the reverse order of normal reproduction. . In this case, in order to decode the P picture P10 as the first picture, the I picture I1, the P picture P1, the P picture P2,.
Decode to picture P9. That is, the decoding operation is performed ten times for decoding the P picture P10.
Similarly, to decode the next P picture P9, 9
,..., And P1 are decoded eight times,..., Twice. The last I picture I1 is 1 like the normal reproduction.
Only one decoding operation is required. As a result, 1 GOP of this example
The total number of decodings necessary for reproducing the data is 55.
Therefore, smooth reproduction is extremely difficult.

As a modification of the first conventional moving image data reproducing method, an image developed is decimated and stored as frame data to realize reverse reproduction with a small number of frame memories. The image quality will be degraded.

In the first reverse playback method, the second conventional technique described in Japanese Patent Application Laid-Open No. H7-95536 has been proposed in order to solve the disadvantage of the reduction in the playback speed during the reverse playback of the conventional first moving image playback apparatus. The MPEG reproducing apparatus stores a bit stream in an image memory and holds a storage position for each picture of the bit stream as table information, thereby improving a bit stream reproducing speed.

However, in order to reproduce a target image by itself, decoding must be performed from the beginning of the data stored in the image memory. For this reason, the reproduction speed depends on the capability of the MPEG decoder, and it is difficult to improve the reproduction speed.

Similarly, in the iterative decoding type reverse reproduction method, a third conventional MPEG reproducing apparatus disclosed in Japanese Patent Application Laid-Open No. 8-223534, in which the reproduction speed is improved in order to improve the real-time performance of the reverse reproduction, is disclosed in US Pat. In the reverse playback, only the core picture is decoded in the forward direction and stored in the memory at the time of reverse reproduction, and then the remaining pictures other than the core picture are read from the memory in the reverse order from the last picture. By decoding with reference to the picture, decoding can be performed from the middle of the GOP.

However, if a predetermined core picture is stored without using the data of the number of core pictures of the GOP, depending on the bit stream, the number of core pictures of the GOP may exceed or be smaller than the set number. In some cases, it is not possible to use the memory efficiently, so that the reproduction speed cannot be improved.

[0018]

The above-mentioned first conventional moving image data reproducing apparatus performs decoding with reference to a past or future image in reverse reproduction, so that compressed data is repeatedly written. The first reverse reproduction method of re-reading and decoding is used. The reproduction speed is reduced by a seek operation for reading the recorded compressed data, and the compressed data is read from the beginning of the read data, that is, the moving image of the moving image is read. The reproduction must be performed in a direction opposite to the reproduction direction, and decoding takes a long time, so that the reproduction speed is further reduced.

Further, in the second conventional moving picture data reproducing apparatus which improves the reproducing speed by using the first reverse reproducing method, it is necessary to perform decoding from the head of the data stored in the image memory. Therefore, the reproduction speed depends on the capability of the MPEG decoder, and there is a disadvantage that it is difficult to improve the reproduction speed.

Further, the third conventional moving picture data reproducing apparatus which improves the reproducing speed by using the first reverse reproducing method stores a predetermined core picture without using the number data of the number of core pictures of the GOP. Therefore, depending on the bit stream, the number of core pictures in the GOP may be too large or too small relative to the set number, and there may be a case where the memory cannot be used efficiently and the reproduction speed cannot be improved. Was.

The second reverse reproduction method, in which reproduced pictures are stored in a memory as frame data and sequentially displayed in the reverse order of the order in which the pictures were stored during reverse reproduction, has no problem with reproduction speed, but the MPEG There is a disadvantage that a large-capacity image frame memory for storing expanded frame data for one GOP unit is required.

An object of the present invention is to provide a moving picture data reproducing apparatus and a reverse reproducing method of moving picture data which solve the above-mentioned drawbacks and improve the reproducing speed with a small capacity image memory by using the memory efficiently. To provide.

[0023]

According to the present invention, there is provided a moving image data reproducing apparatus for decoding a moving image encoded by dividing one sequence of a moving image into groups of pictures (GOP) consisting of a plurality of pictures. Bit stream supply means for reproducing and outputting the bit stream from the medium, decoding means for decoding the bit stream and outputting decoded data, a decoding memory area for holding picture data required for the decoding, and the decoding An image storage means having a display memory area for holding coded data for image display, and a moving image data reproducing apparatus having a function of reproducing the moving image from an arbitrary portion in a reverse direction. pm stream one store to store temporarily the one unit of at least the GOP of the read the bit stream And憶unit, the GOP reproduced for a reference image to be referred to when <br/> decoding of other pictures
A core picture storage means for storing the core picture within said GOP the number and its own memory capacity calculated from that <br/> predetermined number of core picture, the stream temporary storage Stories
Storage means and control of the core picture storage means.
Decoding control means for controlling the entire decoding operation .

In the reverse reproduction method of moving image data according to the present invention, a bit stream to be decoded of a moving image which is obtained by dividing one sequence of a moving image by a group of pictures (GOP) composed of a plurality of pictures is obtained. Decoding and decoding the bit stream with reference to a predetermined number of core pictures in the GOP as a reference picture to be reproduced and output from the medium and referred to when decoding another picture stored in the core picture storage means; Using a moving picture data reproducing apparatus that outputs encoded data, in a reverse reproducing method of moving picture data in which the moving picture is reproduced from an arbitrary part in a reverse direction, wherein the number of core pictures constituting the GOP and the core picture saving those characterized by setting the storage interval is an interval of the core picture storage target arbitrarily based on the memory capacity of the unit A.

[0025]

FIG. 5 shows an embodiment of the present invention.
Referring to FIG. 1, which is similarly denoted by a block with common reference characters / numerals attached to common components, the moving image data reproducing apparatus of the present embodiment shown in FIG. A stream supply source 1 for reproducing a medium common to the image data reproducing apparatus and outputting a bit stream of read data;
MPEG for decoding a bit stream of read data
In addition to a decoder 3 and an image memory 4 storing picture data for display and decoding, a stream temporary storage memory 2 for temporarily storing a bit stream of read data.
A core picture memory 5 for storing a core picture of a GOP calculated from the number and memory capacity of the core pictures in the GOP, and a decoding including control of the stream temporary storage memory 2 and the core picture memory in place of the decoding controller 6 And a decode controller 6A for controlling the entire operation.

The stream temporary storage memory 2 is a memory having a maximum capacity of about 5 Mbits for temporarily storing data read from the stream supply source 1 for at least one GOP, from which data necessary for reverse reproduction is read.

The core picture memory 5 stores the core pictures of the GOP calculated from the number of core pictures in the GOP and the memory capacity that are known in advance, and stores the pictures when decoding and display are necessary during reverse playback. This is a memory in which the display or the MPEG decoder 3 makes reference to pictures.

The decode controller 6A manages the data stored in the stream temporary storage
The EG decoder 3 manages the reading destination of the data at the time of reverse reproduction, the reference picture of the decoded image, and the core picture memory 6.

Next, FIG. 1 is a flowchart showing a core picture saving process for determining a core picture interval to be saved based on the number of core pictures of the target GOP and the number of core pictures storable in the core picture memory 5 and FIG. The operation of the present embodiment will be described with reference to FIG. 3 showing an example of a decoding operation at the time of reverse reproduction of FIG.
During normal playback, the stream temporary storage memory 2 stores the bit stream supplied from the stream source 1
The data is stored for each GOP and transferred to the MPEG decoder 3 at the same time. When the bit stream from the stream source 1 changes to data of a new GOP, the stream temporary storage memory 2 discards the stored previous GOP data if the memory capacity is only one GOP, and stores the new GOP. G
OP data is stored.

The MPEG decoder 3 decodes the transferred data while referring to the pictures in the image memory 4 in the order recorded in the bit stream, and transfers the decoded pictures to the image memory 4. Simultaneously with the transfer of the decoded picture, if the picture is a core picture, the decode controller 6 determines whether or not to save the picture in the core picture memory 5.

Referring to FIG. 2, if the I picture is I1
GOP consisting of 10 P-pictures, P1 to P10
In the following, an example in which the number of storable images in the core picture memory 5 is three will be described. First, a storage interval is calculated (step S1). The core picture to be saved is 10 + 1 =
Since the number of storable core pictures is three, the number of storable core pictures is three, so that 11/3 = 3...

Next, the process proceeds to the determination of the storage interval (step S).
2). This time, since the storage interval has become three or more, the process proceeds to the case where there is a surplus (step S7). In this case, since the remainder is 2, the rear two intervals are added one by one, and every four sheets. Therefore, the saved core pictures are I1, the next third core picture P3, and the next fourth core picture P7. Since three core pictures remain after P7, the storage interval has the same meaning as every four pictures.

If the calculation result of the first storage interval is less than three, the calculation is performed again by subtracting 1 from the number of target core pictures (step S3). If the storage interval is less than one, all the core pictures are stored in the core picture memory 5 (step S6).

If the storage interval is one or more, the first I
Without saving the picture, the calculated interval (1 or 2
The core picture is stored (for each frame) (step S5), and if there is a remainder, one frame is added at intervals from the rear (step S7).

Referring to FIG. 3, first P picture P10
If reverse playback starts when is displayed, the next picture to be displayed is the P picture P9. The decode controller 6A stores the P picture P7 in the core picture memory 5.
Since it is known that the P picture P9 is displayed, decoding of the referenced P picture P8 and P
Since the picture P9 needs to be decoded, the data of P8 and P9 is transferred from the stream temporary storage memory 2 to the MPEG decoder 3.

The decode controller 6A transfers the P picture P7 necessary for decoding the P pictures P8 and P9 from the core picture memory 5 to the decode memory area of the image memory 4. The MPEG decoder 3 decodes the data of the transferred P pictures P8 and P9 using the P picture P7 transferred to the image memory 4, and decodes the P picture P8.
9 is displayed.

To display the next P picture P8, since the P picture P8 remains in the decode memory of the picture memory 4 when the P picture P9 is decoded, it is moved to the display memory area of the picture memory 4. To display. The display of the P picture P7 is performed by transferring the P picture P7 from the core picture memory 5 to the display memory area of the image memory 4.

Similarly, in order to display the next P picture P6, since the data to be referred to is the P picture P3, the picture to be transferred to the image memory 4 is the P picture P3. Are the data of the P pictures P4 to P6.

By repeating this, the display up to the I picture I1 is performed, and the reverse reproduction for one GOP is performed. As a result, the total number of decodings necessary for reproducing one GOP in this example is 2
The number of times is +8 times + 3 times + 2 times. This is a drastic reduction compared to the conventional 55 times.

Further, when the reverse reproduction is continued, the immediately preceding GOP data is transferred from the stream supply source 1 and
Necessary data is stored in the stream temporary storage memory 2 and the core picture memory 5 while decoding by the PEG decoder 3, the last picture of the target GOP is displayed, and the above-described reverse reproduction procedure is repeated.

When there is a B picture between an I picture and a P picture or between a P picture and a P picture, the following operation is performed.

That is, if there is a B picture between the two P pictures P 9 and P 8, the B picture data is transferred from the stream temporary storage memory 2 to the MPEG decoder 3 after displaying the P picture P 9. Decoding and displaying are performed, and then the P picture P8 remaining in the decoding memory of the image memory 4 may be displayed.

As described above, the moving picture data reproducing apparatus according to the present embodiment has the same structure as the conventional apparatus shown in FIG.
The total number of decodings required for OP data reproduction is eight.

Further, P continues from the reverse reproduction of the previous GOP.
Even in the worst case where the previous GOP having a core picture up to picture P9 is newly read, the decoding count of P picture P9 is 10 instead of 2 because it is newly read. The number of times of decoding is 10 times + 3 times + 1 times + 2 times = 16 times, which is 5 times of the conventional method.
Since the number of decodings is reduced as compared with five times, the speed of reverse reproduction can be improved.

Next, a second embodiment of the present invention will be described with reference to FIG. 4 in which constituent elements common to those in FIG. This embodiment is different from the first embodiment in that an image core picture memory 7 in which the image memory 4 and the core picture memory 5 are shared by one memory is provided instead of the image memory 4. It is.

The operation of the present embodiment is basically the same as the operation of the first embodiment. However, by sharing one memory, the core picture stored in the core picture memory area can be used. By changing the mapping instead of the transfer, it is possible to allocate to the picture of the decoding memory in the display / decoding memory area.

As a result, the picture transfer time can be shortened, and the reproduction speed of reverse reproduction can be further improved.

[0048]

As described above, the moving picture data reproducing apparatus and the moving picture data reverse reproducing method according to the present invention comprise a stream temporary storing means for temporarily storing a bit stream, and a core picture storing means. Therefore, the number of core pictures to be stored can be easily changed according to the amount of core picture memory to be used, and the position of the core picture to be stored can be changed according to the number of core pictures of a target GOP. Even if the number of sheets changes, there is an effect that no waste occurs in the core picture memory due to the setting.

Further, by setting the picture remaining in the decode memory as a display picture, reading and decoding of the stream of the picture to be displayed can be shortened, so that the display speed can be increased and the reproduction speed can be improved. .

Further, since the number of decoding times is smaller than that of the conventional first reproducing apparatus having no core picture memory, there is an effect that the reproducing speed is greatly improved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of a moving image data reproducing apparatus according to the present invention.

FIG. 2 is a flowchart showing an example of a moving image data reverse reproducing method which is an operation of the moving image data reproducing device of the present embodiment.

FIG. 3 is an explanatory diagram showing an example of a decoding operation at the time of reverse reproduction of data of the moving image data reproduction device of the present embodiment.

FIG. 4 is a block diagram showing a second embodiment of the moving image data reproducing apparatus of the present invention.

FIG. 5 is a block diagram showing an example of a first conventional moving picture data reproducing apparatus.

FIG. 6 is a flowchart showing an example of a method of reversely reproducing moving image data, which is an operation of the first conventional moving image data reproducing apparatus.

[Explanation of symbols]

 Reference Signs List 1 stream source 2 stream temporary storage memory 3 MPEG decoder 4 image memory 5 core picture memory 6, 6A decode controller 7 image core picture memory

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-8-223586 (JP, A) JP-A-8-223529 (JP, A) JP-A 8-130707 (JP, A) JP-A-8-223 102913 (JP, A) JP-A-7-95536 (JP, A) JP-A 8-223534 (JP, A) JP-A-11-205739 (JP, A) (58) Fields investigated (Int. ⁷ , DB name) H04N 5/91-5/956 H04N ^7/ 24-7/68 G11B 20/10-20/12

Claims (7)

(57) [Claims] 1. A bit stream supply means for reproducing a bit stream to be decoded of a moving image obtained by dividing one sequence of a moving image into groups of pictures (GOP) consisting of a plurality of pictures from a medium and outputting the bit stream. When,
An image having decoding means for decoding the bit stream and outputting decoded data, a decode memory area for holding picture data necessary for the decoding, and a display memory area for holding the decoded data for image display and a storage means, in a moving picture data reproducing apparatus having a function of reproducing in the reverse direction to the moving image from any part, the one unit of at least the GOP of the bit stream where the bit stream supply unit has read one and stream temporary storage memory means for storing the time, since a reference image that references during decoding of other pictures
The number of core pictures of the GOP reproduced by
Core picture storage means for storing a predetermined number of core pictures in the GOP calculated from memory capacity , the stream temporary storage means, and the core picture storage means.
Controls the entire decoding operation including the control of the storage means
A moving image data reproducing apparatus comprising: a decoding control unit . 2. The decoding control means according to claim 1 , wherein
Management of the data stored in the temporary storage means and
Management of the data reading destination of the decoding means during the reverse reproduction
And the reference image of the decoded image corresponding to the decoded data
2. The moving image data reproducing apparatus according to claim 1, wherein the moving image data reproducing apparatus performs management and management of the core picture storage unit . 3. A bit stream supply means for reproducing a bit stream to be decoded of a moving image obtained by dividing one sequence of a moving image into groups of pictures (GOP) comprising a plurality of pictures from a medium and outputting the bit stream. When,
An image having decoding means for decoding the bit stream and outputting decoded data, a decode memory area for holding picture data necessary for the decoding, and a display memory area for holding the decoded data for image display and a storage means, in a moving picture data reproducing apparatus having a function of reproducing in the reverse direction to the moving image from any part, one unit of least said GOP also of the bit stream where the bit stream supply unit has read and stream temporary storage memory means for storing temporarily a core picture below and the stream temporary storage memory means
Control of the entire decoding operation including control of the memory area.
E Bei and decoding control means for said image storage means, referenced when the other picture decoding
A core picture of the GOP reproduced for use as a reference image
A moving picture data reproducing apparatus comprising the core picture memory area for storing a predetermined number of core pictures in the GOP calculated from the number of the pictures and the own memory capacity . 4. The method according to claim 1, wherein the core picture reproduced during the forward reproduction of the moving image is stored, and the bit stream is decoded with reference to the core picture stored during the reproduction in the reverse direction. Or the moving image data reproducing apparatus according to 3. 5. The decoding control means according to claim 1 , wherein:
Management of the data stored in the temporary storage means and
Management of the data reading destination of the decoding means during the reverse reproduction
And the reference image of the decoded image corresponding to the decoded data
The moving image data reproducing device according to claim 3, wherein the moving image data reproducing device performs management and management of the core picture memory area . 6. A bit stream to be decoded for a moving image obtained by dividing one sequence of a moving image into groups of pictures (GOP) composed of a plurality of pictures, reproducing and outputting the core picture, and storing a core picture. As a reference image for reference when decoding other pictures stored in the means.
The video is played back from an arbitrary portion in the reverse direction using a video data playback device that decodes the bit stream with reference to a predetermined number of core pictures in the GOP and outputs decoded data. In the method for reversely reproducing moving image data, a storage interval which is an interval between the core pictures to be stored is arbitrarily set based on the number of core pictures constituting the GOP and a memory capacity of the core picture storage means. Reverse video playback method featuring moving image data. 7. The setting of the storage interval is performed by a first step of calculating a storage interval from the number of core pictures in the GOP and a memory capacity of the core picture storage unit, and the first step of calculating the storage interval. A second step of determining whether or not the storage interval is greater than the number of stored pictures determined by the memory capacity; and, if the storage interval is smaller than the number of stored pictures, A third step of re-calculating the storage interval by subtracting 1; a fourth step of determining whether or not the storage interval calculated in the third step is one or more; A fifth step of storing the core picture at the storage interval of the calculation result except for the leading I picture when the storage interval is one or more as a result of the determination in the step; 1 If the cross-sectional results the storage interval step in and the fifth remainder greater than the stored number is generated results remainder is generated from the rear to the remainder
A seventh step of adding each of the core pictures to the core picture storage unit when the storage interval is less than one as a result of the determination in the fourth step. 7. The moving picture data reproducing apparatus according to claim 6, comprising: