JPH07298267A - Method and device for reproducing compressed image data - Google Patents

Abstract

PURPOSE:To reproduce an image designated by the user when special reproduction is restored to usual reproduction. CONSTITUTION:An image compression mode discrimination means 13 outputs compression data between image units stored in a compression data storage means 15 to a decoded data changeover means 17 based on a command of a special reproduction command means 16 when special reproduction mode is released. An image output when the special reproduction mode is released is loaded again by a decoding means 18 to obtain compression data in the image unit to obtain reference data at decoding. Furthermore, a recording medium read means 12 obtains a read address of compression data outputted from the compression data storage means from an address storage means 14 and restarts the reading of compression data from a compression data recording medium 11 to decode the data from the compression when the special reproduction mode is released and usual reproduction is restarted.

Description

Detailed Description of the Invention

[0001]

The present invention relates to MPEG (Motion Pic).
ture Cording Expert Group; ISO 11172 (MPEG1), ISO 138
18 (MPEG2), hereinafter referred to simply as "MPEG"), relates to a compressed image data reproducing apparatus of a digital moving image data compression method that mixes and compresses intra-image unit compression and inter-image unit compression standardized In particular, the present invention relates to a compressed image data reproducing device for reproducing compressed image data for performing special reproduction such as fast-forwarding and rewinding reproduction of a recording medium on which compressed image data is recorded.

[0002]

2. Description of the Related Art In a digital moving image compression system based on the MPEG system in which compression is performed by interlacing compression in image units and compression between image units, the image data string encodes all of one image data and compresses the data. The compressed image within the image unit that is the compressed image within the performed image unit and the inter-image compressed image that detects the difference by referring to the past image data and compresses the difference of the image data into the compressed image, past and future It is composed of compressed images between image units which refer to images and compress them according to the difference between the images. Then, the inter-image-unit compression is decoded and reproduced by referring to the intra-image-unit compression or the inter-image-unit compression that existed temporally in the past.

A method shown in FIG. 5 is generally used as a method of performing compression coding by intermixing intra-image unit compression and inter-image unit compression represented by the MPEG system.

FIG. 5 is an explanatory view briefly showing an image sequence according to a compression method of a digital moving image in which compression between image units and compression between image units in the MPEG system is mixed and compression-encoded.

In FIG. 5, image data 701 to 71
8 indicates images that are all temporally continuous. The image data 703 and the image data 718 indicated by I are called I picture in the MPEG system, and are the intra-image unit compressed data that are compression-encoded within the image unit. At the time of decoding, the image data is decoded only by the compressed data. It is compressed in a way that is possible. The remaining image data indicated by P or B is inter-image compressed data that refers to another image, detects a difference in image movement or color change, and compression-encodes the difference data. Then, P that refers to the past image data
A picture is referred to as a pictue, and a picture for referring to past and future image data is referred to as a B picture.

FIG. 5A shows a compression method of images arranged in time series, FIG. 5B shows a storage order of compressed data stored by the buffer means at the time of normal reproduction, and FIG. The storage order of the compressed data stored by the buffer means during special reproduction is shown. The bow-shaped arrow in (a) indicates the I picture 70 of the image data corresponding to the start point.
3,718, or Ppicture 703,709,71
2, 715, it indicates that decoding is performed by obtaining the difference and decoding the B picture before and after the B picture. Therefore, the Ppicture is decoded by referring to the Ppicture or Ipicture that existed in the past in time. B picture is decoded by referring to past and future P picture and I picture.

Therefore, assuming that Ipicture 703 is being decoded now, Ipictur compressed next in picture units
All the compressed data until the appearance of e 718 refer to Ipicture 703, which is inherited and compressed in the latest image unit, as a decoding standard. Therefore, P picture or B picture cannot be decoded only by its own compressed data, and it is impossible to decode the compressed data after that without decoding I picture which is the reference for decoding. Is.

As a method of performing such a compression mode,
The full-color video compression standard (MPEG), which is being standardized by ISO, and the H.264 standard for videophone. 261 and the like are representative of these.

Various methods have been proposed as a method for performing special reproduction such as fast-forward reproduction and rewind reproduction in an image reproducing apparatus that compresses by intermixing intra-image unit compression and inter-image unit compression. ing. As a typical one, there is known a technique disclosed in Japanese Patent Laid-Open No. 63-310293, in which special reproduction can be easily realized by decoding and reproducing only compressed image data compressed in image units. This is because the image data compressed within an image unit can be reproduced with only the compressed data. Therefore, by reproducing only this compressed data, the image data compressed between image units is thinned out and reproduced. As a result, fast forward reproduction and rewind reproduction can be performed.

In FIG. 5, according to the MPEG system, the I picture 703 or 718 compressed in the image unit is
Since it is possible to play back only with the compressed data, it is used as a playback reference, and a procedure for playing Bpicture by referring to Ppicture three images ahead is adopted, and if Ipicture and Ppicture are played during special playback, In the example of FIG. 5, the reproduction is performed once for every three images, and if the images are output at a normal output speed, three images are reproduced.
Playback will be performed at double speed. If only Ipicure is reproduced, reproduction is performed once for every 15 images, and if images are output at a normal output speed, reproduction is performed at 15 times speed.

MP for performing special reproduction such as fast-forwarding and rewinding
FIG. 6 shows an example of a reproducing device represented by the EG method.

FIG. 6 is a block diagram showing the structure of a conventional special reproduction apparatus for compressed digital moving image data.

In FIG. 6, reference numeral 81 denotes a recording medium on which image data compressed by performing intra-image unit compression by using intra-image unit compression and reference from another image is recorded. Reference numeral 82 is a reading means for reading the compressed data from the recording medium 81. 8
Reference numeral 3 denotes compressed data read from the reading means 82 and compressed in the image unit, that is, Ipictur.
It is an in-image compressed data extracting means for extracting only e. The signal a is compressed data for inter-picture compression consisting of I picture, P picture and B picture, and the signal b is only I picture by the intra-picture compressed data extraction means 83. Then, after being temporarily stored in the buffer means 84, it is sent to the compressed image data decoding means 85, and the compressed data is decoded to obtain an image output.

That is, during the normal reproduction, all the compressed data are accumulated as shown in FIG. 5B. For example, when decoding the B picture 704 of the next compressed data with respect to the I picture 703, the I picture 703 is decoded. And Ppicture 706
Is required, and Ipicture 703 and Ppicture 706 are also required for the next Bpicture 705, and the Bpicture is decoded by referring to these. And
For the next Ppicture 706, Ipicture 703
Therefore, for Bpicture 707, Ppicture 706
And Ppicture 709 are required. Therefore, FIG.
As shown in (b), the order of accumulation in the buffer means 84 is rearranged and accumulated in a convenient order for the image to be decoded.

In addition, during special reproduction, the special reproduction instructing means 86 which has detected the special reproduction instruction notifies the recording medium reading means 82 that the special reproduction has started, and the intra-image-unit compressed data extracting means 83. With respect to, the special reproduction is performed by outputting an instruction to extract only the compressed data in the image unit from the input compressed data.

On the other hand, when encoding these compressed data, it is necessary to perform weighting and encoding on the high frequency side and the low frequency side. For this reason, space-frequency conversion such as two-dimensional discrete cosine transform (DCT) is used, and a considerably large amount of complicated calculation is required. In the compression method of the image data compressed in the image unit and the image data by the compression between the image units, first, the reference I picture is encoded. This image data is obtained by dividing an image into a plurality of regions, and performing space-frequency conversion such as two-dimensional cosine discrete transform (DTC) on each of the regions, and utilizing the fact that human visual characteristics are insensitive to high frequencies, The compression is performed by allocating a large number of codes. Therefore, these data can be decoded only by the image. Then, P picture or B picture is encoded next. This divides the image into multiple regions,
The area closest to each area is searched from the other referenced images. For this, an area having the smallest difference in each pixel value is selected, and the positional difference and the difference data between each pixel in the area are encoded. Space-frequency conversion is also performed on this difference data, as in the intra-image compression. This reference is made by inheritance, but the standard is Ipictur.
e.

Therefore, in decoding the compressed data, first, the I picture compressed in the image unit is decoded. Then, after Ipicture is decoded, Ppicture
And Bpicture are decoded and the whole picture is restored. In this decoding, the frequency-space conversion is performed in the reverse of the compression, and the decoding is performed. This is done for all pixels, and the number of these pixels is very large in the image data required by recent means, and the calculation of the frequency conversion is also extremely huge. It has become the amount.

For this reason, the decoding of this image data is such that, in order to make the decoding in time at the end of the reproduction, the image one image ahead is always decoded, stored in the buffer, and reproduced and outputted. Always hold. For this reason,
During special playback such as fast forward or rewind, when returning to normal playback, the image data being played back at that time is not already held, and the image data compressed within the next image unit is decoded, The image data is held. Further, the read position on the recording medium 81 may be the read position of the currently decoded image data compressed in the image unit or the middle of searching for the next compressed data compressed in the image unit. Therefore, when this special playback is canceled and the normal playback is resumed, the playback starts from the image data that was compressed within the next image unit that was being played back, or from the image data that was further compressed within the previous image unit. Therefore, it is possible that an image contrary to the user's will be reproduced.

Such a situation will be described in detail with reference to FIG.

For example, when fast-forwarding is performed, Ipicture
703 is the image that is reproduced and output, and Ppicture 706
Is a compressed image between image units that is being decoded.
In order to read the next image data in this state, the read address is already moving to the position of Ppicture 706, Bpicture 707 and Bpicture 710 to Ppicture 712 which are temporally earlier on the recording medium 81, and the next I
It is possible that you are searching for picture 718. At this time,
When the fast-forward reproduction is returned to the normal reproduction, the normal reproduction is started from the B picture 707 to which the read address has been moved, or from the P picture 715 which is further ahead, and the reproduction is restarted from the image against the user's will. Will end up.

As described above, when the special reproduction is switched to the normal reproduction, the normal reproduction is not performed from the reproduced and output image, and there is a possibility that the user or the like does not meet the specification.

[0022]

As described above, when performing special reproduction, the compressed data to be reproduced is read out one after another, decoded, and stored in the buffer. When it is returned, the next image data of the image data being reproduced at that time does not match the position of the read address, and the image before and after that image, such as the image data obtained by compression between image units, is displayed. In the case of inter-image compression in which data is first decoded and then referred to and decoded, there is a possibility that the image is restarted from an image at an address far away from the position of the image designated by the user.

Therefore, an object of the present invention is to provide a compressed image data reproducing apparatus capable of starting reproduction from an image reproduced and output as specified by a user when returning from special reproduction to normal reproduction. Is.

[0024]

According to a first aspect of the present invention, there is provided a compressed image data reproducing method, wherein the compressed data is read from a storage medium in which compressed data obtained by mixing compressed data within image units and compressed data between image units is recorded. In the compressed image data reproducing method, the compressed image data read out is distinguished from the compressed data in the image unit and the compressed data between the image units, and an image to be reproduced subsequently to the compressed data in the image unit is output by the discrimination output. The compressed data between units is extracted, the images for the predetermined number of images are stored in a plurality of storage areas, and the compressed data within the determined image unit is selected in the special reproduction mode, and when the special reproduction mode is released. An image output is obtained by decoding the stored reproducible images of a predetermined number of images.

According to a second aspect of the present invention, there is provided a compressed image data reproducing method, wherein the compressed data is read from a storage medium in which compressed data obtained by mixing compressed data in image units and compressed data between image units is recorded and reproduced. In the reproducing method, the compressed data within an image unit and the compressed data between image units are discriminated from the read compressed data, and the inter-image unit compressed data to be reproduced subsequent to the intra-image unit compressed data is extracted by the discrimination output. Then, the predetermined number of images and the read addresses when the compressed data of the predetermined number of images have been stored are stored in a plurality of storage areas, and in the special reproduction mode, the discriminated compressed data in the image unit is selected. Then, when the special reproduction mode is released, the stored compressed data for the predetermined number of images are read out, and then the read address is used. Decoding the compressed data is read, is intended to obtain an image output.

A compressed image data reproducing apparatus according to a third aspect of the present invention comprises a recording medium reading means for reading the compressed data from a storage medium in which the compressed data in which the intra-image unit compressed data and the inter-image unit compressed data are mixed is recorded. , Special reproduction instructing means for instructing and releasing the special reproduction mode,
An image compression mode discrimination means for discriminating between the intra-image unit compressed data and the inter-image unit compressed data from the read compressed data, and a compression for storing a predetermined number of consecutive images from the output image in a plurality of storage areas. In the special reproduction mode based on the output of the data storage means and the special reproduction instruction means, when the special reproduction mode is canceled by selecting the intra-image compression data discriminated by the image compression mode discrimination means,
The decoded data switching means for selecting the compressed data output from the compressed data storage means and the read address when the storage of the compressed data for the predetermined number of images stored in the compressed data storage means are completed are independent of each other. When the compressed data for a predetermined number of images selected by the address storage means for storing in a plurality of storage areas and the decoded data switching means are read from the compressed data storage means, the output image at that time is used for decoding. When the reading of the compressed data for the predetermined number of images from the compressed data storage means is completed, the compressed data is read from the recording medium reading means by the read address and the compressed data is decoded to obtain an image output. And is equipped with.

[0027]

According to the first aspect of the present invention, the compressed data obtained by mixing the read compressed data in the image unit and the compressed data between the image units is discriminated from the compressed data in the image unit and the compressed data in the image unit, and the discrimination output. The inter-image unit compressed data to be reproduced subsequently to the intra-image unit compressed data is extracted, the predetermined number of images are stored in a plurality of storage areas, and the determined intra-image unit compression is performed in the special reproduction mode. When the data is selected and the special reproduction mode is released, the stored reproducible images of the predetermined number of images are decoded to obtain an image output.

According to a second aspect of the present invention, the compressed data in which the intra-image unit compressed data is intermixed with the inter-image unit compressed data that has been read out is discriminated from the compressed data in which the inter-image unit compressed data is intermixed. Extract the inter-image unit compressed data to be reproduced subsequently to the intra-image unit compressed data, and when the storage of the predetermined number of images and the predetermined number of compressed data is completed, a plurality of read addresses are stored. When the special reproduction mode is released, the compressed data for the predetermined number of images stored in the area is read, and then the compressed data is read by the read address and decoded to obtain an image output.

According to a third aspect of the present invention, the recording medium reading means reads out the compressed data in which the intra-image unit compressed data and the inter-image unit compressed data are mixed from the storage medium, and the special reproduction instructing means instructs and cancels the special reproduction mode. Give instructions. Then, in the special reproduction mode, the image compression mode discrimination means discriminates the compressed data in the image unit from the compressed data read out and the compressed data between image units, and the image compression mode discrimination means outputs the image data in the image unit. The compressed data is extracted, output to the decoding output means, and reproducible images for a predetermined number of images are stored in a plurality of storage areas of the compressed data storage means. At the same time, the read address when the storage of the compressed data for the predetermined number of images stored in the compressed data storage means is finished is stored in a plurality of storage areas independent from each other. When the special reproduction mode is released, the compressed data output from the compressed data storage means is selected, and when the compressed data for the predetermined number of images stored in the compressed data storage means is read out, the read operation is performed. The compressed data is read from the recording medium reading means by an address, and the compressed data is decoded to obtain an image output.

[0030]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the arrangement of a compressed image data reproducing apparatus according to the first embodiment of the present invention. Figure 2
FIG. 2 is an explanatory diagram showing a storage state of an address storage unit and a compressed data storage unit in FIG. FIG. 3 is an explanatory diagram showing the storage order of the compressed data stored in the compressed data storage means of FIGS. 1 and 2 in the process of reproducing the image data compressed by the MPEG method. FIG. 4 is a flow chart showing the processing steps of the trick play instructing means in FIG.

In FIG. 1, 11 is a compressed data recording medium on which compressed data is recorded, 12 is a recording medium reading means for reading the compressed data from the compressed data recording medium 11, and 1
Reference numeral 3 is an image compression mode determining means for determining the image compression mode between the intra-image unit compressed data and the inter-image unit compressed data, 14 is an address storage means for storing a read address, and 15 is a compressed data storage means for storing compressed data. Reference numeral 16 denotes a special reproduction instructing means for switching to either one of the normal reproduction state and the special reproduction state and for instructing the special reproduction from the user or the like. Reference numeral 17 is a decoded data switching means for switching the input of the decoded data according to the reproduction mode, 18 is a decoding means for decoding the compressed data, and 19 is an output means for outputting the image data. Further, 20 is a buffer means for temporarily storing, 21 is a storage area for selecting an area for recording in either of the two areas A or B prepared in the address storage means 14 and the compressed data storage means 15. It is a determination means. In addition, the thin arrows in the figure show the control system, and the thick arrows show the flow of data relating to the image system.

First, in the case of normal reproduction, the special reproduction instructing means 16 indicates that the state of the image compression data reproducing apparatus of the present embodiment is normal reproduction, the recording medium reading means 12 and the image compression mode determining means, respectively. 13, the decoded data switching means 17, the decoding means 18 and the storage area discrimination means 21 are informed, and the normal reproduction operation is instructed. Compressed data recording medium 11
Then, the compressed data is read by the recording medium reading means 12 and output to the image compression mode judging means 13. The image compression mode discrimination means 13 passes all the data of the compressed data in the image unit and the compressed data between the image units of the input compressed data, and is sequentially accumulated in the buffer means 20, and when the required data amount is reached, the decoded data The data d is output to the switching means 17. The content of the data a at this time becomes the content of the data d as it is. Then, the decoded data switching means 17 selects the data d based on the normal reproduction instruction from the special reproduction instructing means 16, transfers it to the decoding means 18 for decoding, and outputs the normal reproduction from the output means 19. Image data is output.

Next, the case of special reproduction such as rewinding or fast-forwarding will be described.

First, the trick play instructing means 16 respectively includes a recording medium reading means 12 and an image compression mode determining means 1.
3, the decoding data switching means 17, the decoding means 18 and the storage area discriminating means 21 are instructed to perform the special reproduction operation. Data a read from the recording medium reading means 12 as in the normal reproduction
The image compression mode determination means 13 determines to extract the intra-image compression data. Therefore, of the data a, only the compressed data for intra-image compression is extracted and output to the buffer means 20 as the data d. The buffer means 20 successively stores the input compressed data as in the normal reproduction, and when it reaches a required data amount, outputs it to the decoded data switching means 17 as data d. However, the content of the data d at this time is only the intra-image compressed data. Then, the decoded data switching means 17 selects the data d based on the special reproduction instruction from the special reproduction instruction means 16,
It is transferred to the decoding means 18 to be decoded, and the output means 19 outputs the special reproduction image data. Therefore, as for the image during special reproduction, a discontinuous image in which only the compressed data within the image unit is decoded is reproduced by thinning out the compressed data between image units with respect to the continuous image during normal reproduction.

On the other hand, as described above, when the image compression mode discrimination means 13 retrieves the intra-image compression data, the compression data is transferred to the decoded data switching means 17 as the data d, and at the same time, The image compression mode discrimination means 13 is a continuous image in the normal compressed reproduction among the remaining compressed data between image units, and the compressed data to be decoded and reproduced next in time is compressed data as data b consisting of a predetermined number of images. It is transferred to the storage means 15.
The compressed data storage means 15 has two independent storage areas A and B, and the storage area determination means 21 activated by the special reproduction instruction from the special reproduction instruction means 16.
According to the determination, the data b is stored in either one of the storage areas A or B. Then, when the storage of the predetermined number of sheets is completed, the image compression mode discrimination means 13 stores the read address at the time of the termination, so that the special reproduction instruction means 1
The recording medium reading unit 12 requests the address storing unit 14 via 6 to store the reading address at the time when the reading of the predetermined number of images is completed. here,
The address storage means 14 has two storage areas A and B that match the two storage areas A and B of the compressed data storage means 15. Then, the storage area discrimination means 21 activated by the trick play instruction means 16 matches the storage area A or B of the address storage means 14 so as to coincide with either the area A or B in which the data b is stored in the compressed data storage means 15. Select. Then, when a predetermined number of pieces of compressed data are stored in the compressed data storage means 15 by the discrimination of the image compression mode discrimination means 13, the read address at that time is detected, and for example, the read address is set to Adw and the next compressed data is stored. The read address of is written. That is, the compressed data storage means 1 is selected based on the selection of the storage area determination means 21.
If the data b is stored in the area B of No. 5, the read address of the next image data is stored in the area B of the address storage means 14 as Adw. Then, the compressed data storage means 1 stores compressed data for a predetermined number of images to be decoded and reproduced.
When the data is output from the storage area A or B of No. 5 and the storage of the predetermined number of sheets is finished to be reproduced, the storage medium reading means 12 reads it as the read address at the time of the end.

In this way, the compressed data between the image units of the area A previously stored in the compressed data storage means 15 is
The storage will be maintained until the storage of a predetermined number of pieces of compressed data between image units is completed. With respect to the compressed data between image units that are input thereafter, the storage area determination means 2
Based on the selection of 1, the area B of the compressed data storage means 15
The areas are alternately recorded in the order of area A and area B. The read address at this time is also stored in the areas A and B of the address storage means 14 in association with the storage area of the compressed data storage means 15.

FIG. 2 is an explanatory diagram showing a state in which the compressed data between image units are stored in the compressed data storage means 15 and a state in which the read address is stored in the address storage means 14.

In FIG. 2, it is assumed that special reproduction has started. Then, as described above, the image compression mode discriminating means 13 stores the data b in the storage area of the compressed data storage means 15 in the area A selected by the storage area discriminating means 21 in the form of b = NEXT1 for a predetermined number of sheets. It When the storage is completed, the read address is the storage medium reading means 1
According to 2, the data is stored in the area A of the address storage means 14 in the form of Adw = me1. Next, when the data to be decoded and reproduced is input, the NE is displayed in the area B of the compressed data storage means 15.
It is recorded in the form of XT2, and the read address is also recorded in the area B of the address storage means 14 as Adw = me2. Then, the data is recorded in the area A of the compressed data storage means 15.
When NEXT2 finishes recording, next NEXT3 is overwritten on NEXT1 recorded in area A, NEXT1 is discarded and a new NEXT3 is created.
Is memorized. And the read address by NEXT3 is
The read address Adw by NEXT1 stored in the area B of the address storage means 14 is discarded and recorded as me3.

In this way, each time the compressed data is successively input, the areas of the compressed data storage means 15 and the areas of the address storage means are interlocked by the storage area discriminating means 21 and alternately repeated. Will be updated.

Next, the decoding of the compressed data when the special reproduction is canceled and the normal reproduction is resumed will be described.

In general, the user wants to quickly search for an image intended by him / her and desire normal reproduction from that image. Therefore, when special reproduction is canceled, the image next to the image being reproduced is reproduced during normal reproduction. The corresponding image must be output.

When the special reproduction is canceled by the special reproduction instructing means 16, the recording medium reading means 12, the image compression mode judging means 13, the decoded data switching means 17 and the decoding means 18 are instructed to return to the normal reproduction. . At this time, for example, when the area of the compressed data being recorded is A, the read address of the area A of the address storage means 14 is used.
The compressed data of the address stored in this area B is stored in the area B of the corresponding compressed data storage means 15.
The trick play instruction means 16 is the compressed data storage means 15.
The storage medium discriminating means 21 to output the compressed data in the area A to the decoded data switching means 17, and the recording medium reading means 12 to read the address stored in the area A. The storage means 15 stores data c
As a predetermined number of image data, the decoded data switching means 1
Output to 7.

At the same time, when the recording medium reading means 12 finds the read address of the area A of the address storage means 14 corresponding to the compressed data stored in the area A of the compressed data storage means 15, the address storage means 14 stores the read address. When the reading of the read address into the area A is started to read the compressed data of the corresponding address from the compressed data recording medium 11, the operation at the normal reproduction is restarted. The image compression mode determination means 13 stores all the compressed data of the intra-image unit compressed data and the inter-image unit compressed data of the normal operation in the buffer means 2.
The data is transferred to 0, is temporarily stored until the required data amount is reached, and is then transferred to the decoded data switching means 17 as data d. In the decrypted data switching means 17, first, immediately after the decryption operation is released, the compressed data storage means 1 described above is used.
Switching is performed to transfer the data c in the area A of 5 to the decoding means 18. After transferring the data c, the data d which is a normal operation is selected and transferred to the decoding means 18, and an image is output through the output means 19.

Regarding the compressed data on the compressed data recording medium 11, the intra-image unit compressed data or the inter-image unit compressed data is sequentially stored in the buffer unit 20 through the recording medium reading unit 12 and the image compression mode judging unit 13 by restarting normal reproduction. Transferred. However, the compressed data read from the compressed data recording medium 11 does not always start with the intra-image compressed data. That is, at this time, the data d immediately after being read from the compressed data recording medium 11 has a high probability of being compressed data by the compression between image units, and cannot be decoded by the data alone. Therefore, decoding requires compressed data of reference images temporally before and after which the inter-image unit compressed data should refer.

Therefore, the image data composed of the data c in the area A of the compressed data storage means 15 at the time when the reproduction is canceled is not always the compressed data based on the inter-image unit compressed data. However, since the image output is held in the output means 19, the trick play instructing means 16 reloads the held image data f from the output means 19 to the decoding means 18, and thereby the data d is stored. It is possible to obtain compressed data in the past in terms of time, and as a result, the output means 1
The image output of 9 is treated as an I picture, and by using it, even the compressed data between image units stored in the area of the compressed data storage means 15 can be demodulated into a predetermined image.
As for the compressed data read by the recording medium reading means 12 following this, the compressed image data in the image unit or the compressed data between the image units is sequentially transferred from the image compression mode discrimination means 13 by the normal reproduction through the buffer means 20. Therefore, normal image formation can be performed.

Therefore, the number of images of the compressed data stored in the compressed data storage means 15 needs a capacity capable of recording the compressed data for the time until the recording medium reading means 12 returns to the normal reading from the compressed data recording medium 11. is there. Specifically, immediately after the completion of the movement of the read position to the designated read address, reading is started, the read compressed data is stored in the buffer means 20, and the buffer means 20 adjusts the timing to switch the decoded data. The means 17 can switch from the data c from the compressed data storage means 15 to the data d which is the first compressed data after the normal reproduction is resumed, and thereafter, the normal reproduction is started.

Next, how much compressed data should be stored so that it can be introduced into normal reproduction will be described with reference to FIG.

FIG. 3 is an explanatory diagram showing the recording order of the image data stored in the data memory of FIGS. 1 and 2 in the process of reproducing the image data compressed by the MPEG system.

In FIG. 3, (a) shows temporally continuous image data read from the compressed data recording medium 11. (B) is the buffer means 2 of FIG. 1 during normal reproduction
It is the storage order of the compressed data stored with 0. (C) shows the storage order of the compressed data stored in the area A or the area B by the compressed data storage means of FIG. 1 during special reproduction. It should be noted that, in the figure, what is indicated by I is the compressed data within a picture unit, which is I picture. What is shown as B is compressed data between image units obtained by referring to past and future images, and is B picture. Moreover, what is shown as P is compressed data between image units obtained by referring to a past image, which is P picture.

The bow-shaped arrow in FIG. 3A is the I picture 303, 318 of the image data corresponding to the starting point, or Ppict.
In ure 306, 309, 312, and 315, compression is performed by referring to the difference between the preceding and following Bpictures in order to decode them.

First, the case of high speed reproduction for reproducing only the compressed image data in the image unit, that is, fast forward will be described.

In FIG. 3, it is assumed that, for example, when fast-forwarding is performed, when the Ipicture 303 is an image being reproduced and output, the normal reproduction is resumed. At this time, the recording medium reading means 1
The address search position on the second compressed data recording medium 11 is
Bpicture 304 or Bpictur located ahead in time
The position of compressed data such as e 305 and Ppicture 309, or the next Ipicture 318 may be searched.

The spatial read position on the recording medium must be moved from the position of these compressed data to the data position of the image of B picture 301 which must be actually reproduced. For example, if the read position is Bpict
If it takes 0.1 seconds to move to the position of the ure 301, the compressed data for 0.1 seconds or more, which is the image data for this time, is stored in either area of the compressed data storage means 15. It will be good. In this embodiment, Bpicture 301, 302, Ppicture 306, Bpi
Compressed data storage means 1 for only five ctures 304 and 305
It is stored in 5.

In this example, all Ipictures 30
However, in the case of higher speed fast forward or rewind special reproduction, every I picture is set to 2
In some cases, it is played back every other sheet. Also in this case, the same operation is performed, and by storing the image data for the time corresponding to the return of the position of the reading means, it is possible to smoothly return from the image being reproduced to the normal reproduction.

Next, the storage order of compressed data according to the compressed data storage procedure shown in FIGS. 1 and 2 will be described.

A typical image appearance pattern in the MPEG system is one IPicture and BPicture as shown in FIG.
2 pictures, then 1 PPicture and 2 Bpictures, repeated 4 times, which corresponds to 1 sequence. After that, it is repeated for each sequence. In the case of NTSC, the image data is about 30 images (29.97 Hz) per second, and at a bit rate of 1.5 Mbps, this sequence is 15 images in total, so it is just 0.5 seconds. Therefore, IPicture, which is the compression within the image unit, appears once every 0.5 seconds. Further, in the case of NTSC, it corresponds to the output of three images in about 0.1 seconds. Therefore, in the above embodiment, the normal 1.
Continuous playback is possible even if it takes about 5 times longer. Then, during the normal reproduction, since the decoding order described above is followed, the data is recorded on the buffer means 20 in the order shown in FIG. That is, in the MPEG system, since the recording order and the display order are not the same as described above, it is necessary to determine the image data that should be output temporally following the in-image compressed data.

Therefore, in the case of the MPEG system, an area called temporal reference indicating the display order is prepared for each image data, and this indicates the display order. Therefore, only the compressed data in which the numerical value of the temporal reference area in this data is larger than the intra-image compressed data reproduced at the high speed reproduction may be stored in the compressed data storage means 15. Then, this determination may be performed by the image compression mode determination means 13.

Next, such special reproduction processing and recovery processing from special reproduction will be described with reference to FIG.

Next, a second embodiment of the present invention will be described with reference to FIG.

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

In FIG. 4, 511 is a compressed data recording medium on which compressed data is recorded, 512 is a recording medium reading means for reading compressed data from the compressed data recording medium 511, and 513 is image compression for discriminating the image compression mode. The form discriminating means, 514 is an address storing means for storing a read address, 515 is a compressed data storing means for storing compressed data, and 516 is a special reproduction instructing means for instructing special reproduction from a user or the like. Reference numeral 517 is a decoded data switching means for switching the input of the decoded data according to the reproduction mode, 518 is a decoding means for decoding the compressed data, and 519 is an output means for outputting the image data. And 520 is a buffer means. In addition, the thin arrow in the figure indicates the control system,
The bold arrows indicate the flow of data relating to the image.

In the second embodiment having such a configuration, the operation at the time of normal reproduction and the operation of decoding the compressed data at the time of special reproduction are the same as those of the first embodiment described above, and therefore only the differences will be described here. .

First, when performing special reproduction, the special reproduction instructing means 516 is the recording medium reading means 512, the image compression mode determining means 513, the address storing means 514, the compressed data storing means 515, the decoded data switching means 517 and the decoding. The means 518 is instructed to perform the trick play operation. In the image compression mode discrimination means 513, of the compressed data a read from the compressed data recording medium 511 by the recording medium reading means 512, only the compressed data by intra-image compression, that is, Ipicture, is extracted and is passed through the buffer means 520. Obtain the data d. Then, similarly to the first embodiment described above, the data d is selected by the decoded data switching means 517, decoded by the decoding means 518, and the image output is obtained by the output means 519.

On the other hand, compressed data between image units, that is, Bpi
cture and Ppicture are the image compression mode determination means 513.
Of the two storage areas A and B which the compressed data storage means 515 has independently of each other,
Stored as data b. Then, the read address at the time when the storage in the area A is completed is the storage medium reading means 5
12 is detected in synchronism with the end of storage of the image compression mode discrimination means 513, and is first stored in the area A of the two independent storage areas A and B of the address storage means 514 as the read address Adw. It That is, the inter-image compressed data b stored in the area A of the compressed data storage means 515 and the read address Adw of the data are stored in the area A of the address storage means 514 having the same attribute.

Upon completion of such storage operation, the compressed data stored in the area A of the compressed data storage means 515 is transferred to the area B, and the image compression mode discrimination means 513 stores the data b in the area A of the compressed data storage means 515. Compressed data is newly stored. In synchronization with the operation, the read address Adw of the area A of the address storage means 514 is also transferred to the area B and newly stored in the area A. That is, in the storage areas of the address storage means 514 and the compressed data storage means 515, the storage area is always stored in the area A, and when the storage is completed, the data is transferred to the area B and the above operation is repeated.

When the special reproduction is canceled, the data c in the area B of the compressed data storage means 515 is transferred to the decoding means 518 via the decoded data switching means 517. Normal,
Since the data c is compressed data between image units, the data itself cannot be decoded. Therefore, the decoding requires the compressed data of reference images temporally before and after which the inter-image unit compressed data should refer to. Therefore, when the reproduction is canceled, the image output is performed by the output unit 519.
Since the special reproduction instructing means 516 reloads the held image data f from the output means 519 to the decoding means 518,
It is possible to obtain compressed data that is temporally past. At the same time, the read address Adr stored in the area B by the address storage means 514 is used to specify the address of the recording medium read means 512, and the normal reproduction is started.

As described above, in the compressed image data reproducing apparatus of the present embodiment, the compressed data storage mediums 11 and 5 in which the intra-image unit compressed data and the inter-image unit compressed data are mixed.
Recording medium reading means 1 for reading the compressed data from 11
2, 512, special reproduction instructing means 16 and 516 for instructing and canceling the special reproduction mode, and an image for discriminating between the compressed data in image units and the compressed data between image units from the read compressed data. Compression mode determination means 13,
513, compressed data storage means 15 and 515 for storing a predetermined number of continuous images from the output image in the plurality of storage areas A and B, and special reproduction mode based on the outputs of the special reproduction instruction means 16 and 516. At this time, decoding is performed by selecting the compressed data in the image unit discriminated by the image compression mode discrimination means 13 and 513, and selecting the compressed data output from the compressed data storage means 15 and 515 when the special reproduction mode is released. The data switching means 17, 517 and the read address when the storage of the compressed data for the predetermined number of images stored in the compressed data storage means 15, 515 are stored in a plurality of independent storage areas A, B. Address storage means 14 and 514 to be stored and the decoded data switching means 17 and 517 to select the compressed data storage means 1.
When the compressed data for the predetermined number of images is read out from 5, 515, it is decoded using the output image at that time, and when the read out of the compressed data for the predetermined number of images from the compressed data storage means 15, 515 is completed. Decoding means 18518 for reading compressed data from the recording medium reading means 12, 512 at the read address and decoding the compressed data to obtain an image output, and decoding output means comprising output means 19, 519. This is an embodiment of claim 3.

In the present embodiment, the recording medium reading means 12, 512 reads the compressed data in which the intra-image unit compressed data and the inter-image unit compressed data are mixed from the compressed data storage mediums 11, 511, and the special reproduction instructing means 16 , 516
Instruct the special playback mode and cancel it. Then, in the special reproduction mode, the image compression mode discrimination means 1
3, 513, it discriminates between the in-image unit compressed data and the inter-image unit compressed data from the read compressed data, and the output of the image compression mode discriminating means 13, 513 extracts the in-image unit compressed data. Decoding means 18, 5
18 and output means 19, 519, and outputs to a decoding output means, and stores a predetermined number of images in a plurality of storage areas A, B of the compressed data storage means 15, 515.
At the same time, the read address when the storage of the compressed data for the predetermined number of images stored in the compressed data storage means 15, 515 is changed to a plurality of independent storage areas A,
Remember in B. Then, when the special reproduction mode is released, the compressed data output from the compressed data storage means 15, 515 is selected, and the compressed data storage means 1 is selected.
When the compressed data for the predetermined number of images stored in 5, 515 is read, the compressed data is read from the recording medium reading means 12, 512 by the read address, and the compressed data is decoded to obtain an image output.

That is, when the special reproduction is canceled, the image compression mode determining means 13,
513, the compressed data between image units stored in the compressed data storage means 15, 515 is converted into the decoded data switching means 17,
Output to 517. The image output at the time of special reproduction cancellation is reloaded by the decoding means 18 and compressed data within an image unit is obtained to obtain reference data at the time of decoding. Further, the recording medium reading means 12, 512 stores the read address of the compressed data output from the compressed data storage means 15, 515 in the address storage means 1.
Compressed data recording media 11, 51
When the reading of the compressed data is restarted from 1, the data is compounded by the compression when the special reproduction is released, and the normal reproduction is resumed.

Therefore, when the special reproduction mode is canceled, the predetermined number of images stored in the compressed data storage means 15, 515 are decoded by the decoding means 18, 518 to obtain an image output, and then the reading is performed. Since the compressed data can be read and decoded by the address and the image output can be obtained, the reproduction from the reproduction output image as specified by the user can be started, and the normal reproduction mode can be easily entered during that time. Therefore, when returning from special playback to normal playback,
It is possible to start reproduction from the image which is reproduced and output as specified by the user.

The present embodiment also uses the recording medium reading means 1
From the compressed data obtained by mixing the intra-image-unit compressed data and the inter-image-unit compressed data read in 2, 512, the image compression mode discrimination means 13, 513 discriminates between the intra-image-unit compressed data and the inter-image-unit compressed data. Then, the discriminative output is used to extract the inter-image unit compressed data to be reproduced subsequently to the intra-image unit compressed data, and the images of the predetermined number of images are stored in the plurality of storage areas of the compressed data storage means 15 and 515. When the special reproduction mode is selected, the determined compressed data within the image unit is selected, and when the special reproduction mode is released, the stored predetermined number of images are decoded to obtain an image output. Can be the compressed image data reproducing method according to the first embodiment.

Therefore, when the special reproduction mode is released, the image output is obtained by decoding the image of the predetermined number of images stored in the compressed data storage means 15, 515, so that the recording medium is read from the storage medium. It is possible to secure a time until reading is performed by the means 12 and 512, and it is possible to easily enter the normal reproduction mode. Therefore, when returning from the special reproduction to the normal reproduction, the reproduction can be started from the image which is reproduced and output as specified by the user.

In this embodiment, the recording medium reading means 1 is used.
2, 512, the compressed data in the image unit and the compressed data between the image units are mixed, and the compressed data in the image unit and the compressed data between the image units are discriminated from each other.
The discrimination output is used to extract the inter-image unit compressed data to be reproduced subsequently to the intra-image unit compressed data, and when the storage of the predetermined number of images and the predetermined number of compressed data is completed, the read address is set. Storage in a plurality of storage areas, and when the special reproduction mode is canceled, the stored compressed data for the predetermined number of images is read out, and then the compressed data is read out by the read address and decoded to obtain an image output. This can be used as the compressed image data reproducing method of the second embodiment.

Therefore, the image for the predetermined number of images stored when the special reproduction mode is released is decoded to obtain the image output, and thereafter the compressed data is read by the read address and decoded to obtain the image output. Because you can
It is possible to start reproduction from the reproduction output image as specified by the user and easily enter the normal reproduction mode. Therefore, when returning from the special reproduction to the normal reproduction, the reproduction can be started from the image which is reproduced and output as specified by the user.

By the way, in each of the above-described embodiments, the compressed data storage means 15, 51 is generated when the special reproduction mode is released.
5, a predetermined number of images stored in the decoding unit 5, decoding means 18,
Although the image output is obtained by decoding at 518, in the case of implementing the present invention, a plurality of memories may be prepared and images of a predetermined number of images may be alternately stored, or the images may be sequentially stored in a plurality of memory areas. It is also possible to store and sequentially read from a specific direction. In any case, it is sufficient that the predetermined number of images stored when the special reproduction mode is released can be output. In particular, if the image for the predetermined number of images is the one in which the compressed data in the image unit is stored in the head, it is possible to form the image of the following compressed data between image units.
In this type of embodiment, there is no need to feed back the image output from the output means 19 and 519, so that the control becomes simple.

Of course, it is only necessary that the image of the compressed data between image units can be stored by a predetermined number of images. In particular, in the case of storing a predetermined number of images of the compressed data between image units, the memory capacity can be reduced, which is inexpensive.

Further, storing the predetermined number of images in the compressed data storage means 15 and 515 means the compressed data recording medium 1
It suffices to be able to store a sufficient number of images to secure the time for reading out 1,511.

[0079]

As described above, in the compressed image data reproducing method according to the first aspect, the compressed data in the image unit and the image unit are obtained from the compressed data in which the read compressed data in the image unit and the compressed data between the image units are mixed. The compressed image data is discriminated from the inter-compressed data, the inter-image compressed data to be reproduced subsequently to the intra-image compressed data is extracted by the discrimination output, and a predetermined number of images are stored in a plurality of storage areas.
In the special reproduction mode, the discriminated compressed data in the image unit is selected, and when the special reproduction mode is released, the predetermined number of stored images are decoded to obtain an image output.

Therefore, since the predetermined number of images stored when the special reproduction mode is released are decoded to obtain an image output, it takes time to read from the storage medium by the recording medium reading means. It can be secured and meanwhile, the normal playback mode can be easily entered. Therefore, when returning from the special reproduction to the normal reproduction, the reproduction can be started from the image which is reproduced and output as specified by the user.

In the compressed image data reproducing method according to the second aspect, it is possible to discriminate between the intra-image unit compressed data and the inter-image unit compressed data from the compressed data obtained by mixing the read in-image unit compressed data and inter-image unit compressed data. When the determination output is performed, the inter-image unit compressed data to be reproduced subsequently to the intra-image unit compressed data is extracted, and when the storage of the predetermined number of images and the predetermined number of compressed data is completed, The read addresses are stored in a plurality of storage areas, and the compressed data for the predetermined number of stored images are read when the special reproduction mode is released, and then the compressed data is read and decoded by the read addresses to output an image. To get

Therefore, a predetermined number of images stored when the special reproduction mode is released are decoded to obtain an image output, and thereafter, the compressed data is read and decoded at the read address to obtain an image output. Because you can
It is possible to start reproduction from the reproduction output image as specified by the user and easily enter the normal reproduction mode. Therefore, when returning from the special reproduction to the normal reproduction, the reproduction can be started from the image which is reproduced and output as specified by the user.

According to another aspect of the compressed image data reproducing apparatus of the present invention, the recording medium reading means reads the compressed data in which the intra-image unit compressed data and the inter-image unit compressed data are mixed from the storage medium, and the special reproduction instructing means performs the special reproduction. Instruct mode and cancel it. Then, in the special reproduction mode, the image compression mode discrimination means discriminates the compressed data in the image unit from the compressed data read out and the compressed data between image units, and the image compression mode discrimination means outputs the image data in the image unit. Extract the compressed data, output it to the decoding output means, and reproduce a predetermined number of reproducible images.
The compressed data is stored in a plurality of storage areas of the storage means. At the same time, the read address when the storage of the compressed data for the predetermined number of images stored in the compressed data storage means is finished is stored in a plurality of storage areas independent from each other. When the special reproduction mode is released, the compressed data output from the compressed data storage means is selected, and when the compressed data for the predetermined number of images stored in the compressed data storage means is read out, the read operation is performed. The compressed data is read from the recording medium reading means by an address, and the compressed data is decoded to obtain an image output.

Therefore, a predetermined number of images stored when the special reproduction mode is released are decoded to obtain an image output, and thereafter, the compressed data is read and decoded at the read address to obtain an image output. Because you can
It is possible to start reproduction from the reproduction output image as specified by the user and easily enter the normal reproduction mode. Therefore, when returning from the special reproduction to the normal reproduction, the reproduction can be started from the image which is reproduced and output as specified by the user.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a compressed image data reproducing device according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a storage state of an address storage unit and a compressed data storage unit in FIG.

FIG. 3 is an explanatory diagram showing a storage order of the compressed data stored in the compressed data storage means of FIGS. 1 and 2 in the process of reproducing the image data compressed by the MPEG system.

FIG. 4 is a block diagram showing a configuration of a compressed image data reproducing device according to a second embodiment of the present invention.

FIG. 5 is an explanatory view briefly showing an image sequence according to a compression method of a digital moving image in which compression between image units and compression between image units in the MPEG system are mixed and compression encoding is performed.

FIG. 6 is a block diagram showing a configuration of a conventional special reproduction device for compressed digital moving image data.

[Explanation of symbols]

 11, 511 Compressed data recording medium 12, 512 Recording medium reading means 13, 513 Image compression mode discrimination means 14, 514 Address storage means 15, 515 Compressed data storage means 16, 516 Special reproduction instruction means 17, 517 Decoded data switching means 18 , 518 Decoding means 19, 519 Output means 20, 520 Buffer means

Claims (3)

[Claims] 1. A compressed image data reproducing method for reading and reproducing the compressed data from a storage medium in which compressed data obtained by mixing compressed data within an image unit and compressed data between image units is recorded. The compressed data within image unit and the compressed data between image units are discriminated, and the compressed data between image units to be reproduced following the compressed data within image unit is extracted by the discrimination output, and a plurality of images corresponding to the predetermined number of images are extracted. Stored in the memory area of the special reproduction mode, the compressed data in the determined image unit is selected in the special reproduction mode, and when the special reproduction mode is released, the stored reproducible images of the predetermined number of images are decoded. A method for reproducing compressed image data, characterized in that the image output is obtained as a result. 2. A compressed image data reproducing method for reading and reproducing the compressed data from a storage medium in which compressed data obtained by intermixing compressed data in image units and compressed data between image units is recorded. The compressed data within the image unit and the compressed data between the image units are discriminated, and the discriminated output extracts the compressed data between the image units to be reproduced subsequently to the compressed data within the image unit. When the read address when the storage of the compressed data for the number of images is completed is stored in a plurality of storage areas, and the compressed data in the determined image unit is selected in the special reproduction mode, and the special reproduction mode is released. The compressed data for the predetermined number of stored images are read out, and then the compressed data is read out by the read address and decoded to output an image. Compressed image data reproducing method comprising Rukoto. 3. A recording medium reading means for reading the compressed data from a storage medium in which compressed data obtained by mixing compressed data in image units and compressed data between image units is recorded, and a special reproduction mode instruction and its cancellation. Special reproduction instructing means for instructing, image compression mode discrimination means for discriminating between the in-image unit compressed data and the inter-image unit compressed data from the read compressed data, and a predetermined number of consecutive images from the output image In a plurality of storage areas, and in the special reproduction mode based on the output of the special reproduction instructing means, the compressed data in the image unit discriminated by the image compression mode discriminating means is selected, and the special reproduction mode is selected. And a decoded data switching means for selecting the compressed data output from the compressed data storage means when stored in the compressed data storage means. Address storage means for storing the read addresses when the storage of the compressed data for the predetermined number of images is completed in a plurality of storage areas independent from each other, and selected by the decoded data switching means. When the compressed data for the predetermined number of images is read, the output image at that time is used for decoding, and when the read of the compressed data for the predetermined number of images is completed from the compressed data storage means, the recording is performed by the read address. A compressed image data reproducing apparatus, comprising: a decoding output unit that reads compressed data from a medium reading unit and decodes the compressed data to obtain an image output.