KR100707112B1 - Storage medium and method of making new record of image data to the same - Google Patents

Abstract

Disclosed are a storage medium in which different image data are alternately recorded, and a method of updating image data in the storage medium. Even-numbered, odd-numbered frames, or images of 3, 4, .. multiples of the plurality of frames constituting the recorded first image data are deleted, and new second image data is recorded at the deleted position. In addition, the image data is divided into image blocks composed of a plurality of frames at predetermined time intervals, and recorded on the storage medium for each image block. Even-numbered blocks, odd-numbered blocks, or blocks of 3, 4, ... multiples of the first image data are deleted, and blocks of the second image data are recorded at the deleted positions.

Description

Storage Medium and Method of Making New Record of Image Data to the same}

1A and 1B are schematic diagrams illustrating a data structure of a storage medium when updating moving picture data in a repeat mode according to the related art.

FIG. 2 is a flowchart for explaining update of moving picture data in the repeat mode shown in FIGS. 1A and 1B.

3 is a schematic diagram showing a data structure of a storage medium when updating moving picture data in a repeat mode according to the first embodiment of the present invention.

FIG. 4 is a flowchart illustrating a method of updating image data in the storage medium shown in FIG. 3 according to the first embodiment of the present invention.

5 is a schematic diagram showing a data structure of a storage medium when updating moving picture data in a repeat mode according to a second embodiment of the present invention.

6 is a flowchart illustrating a method of updating image data blocked in the storage medium shown in FIG. 5 according to the second embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

101, 311: 1-1 frame 103, 313: 1-3 frame

201, 321: 2-1st frame 202, 322: 2-2nd frame

411: 1-1 video block 421: 2-1 video block

The present invention relates to a storage medium for image data, and more particularly, to a method of deleting / recording image data in a repeat mode and a storage medium having a data structure in the repeat mode.

The storage of moving picture data generally precedes compression. In addition, the compressed data is stored in a storage medium having a large capacity. Video data is a sequence of images of one frame constituting one screen, consisting of 30 frames per second. In the case of 30 frames per second (usually TV video), the video looks like a seamless human eye, but in the case of movies, 24 frames are used. However, in DVR (Digital Video Recorder), users can reduce the recording speed per second by using 1/2 (2 frames per second) or 1/15, ... and so on.

When the format in which an image is displayed is an interlace scan method, first, an image signal is sequentially applied to odd-numbered scan lines, and then an image signal is sequentially applied to even-numbered scan lines. . Thus, although an image of 30 frames per second is actually displayed, it causes the effect of visually displaying an image of 60 fields per second. However, when the interlaced scanning method implements high resolution, an image flickers between an image displayed on odd-numbered scan lines and an image displayed on even-numbered scan lines. This is due to the longer period of the horizontal scanning signal in the case of high resolution.

In addition, when the format in which the image is displayed is for the progressive scan method, the image signal is sequentially applied from the first scan line of the screen. This method has a disadvantage in that a high resolution image can be displayed regardless of the period of the horizontal scanning signal.

In addition, standards on how to compress a video include MPEG1, 2, 4, 7 and 21. The standards vary depending on the storage medium and data transmission speed where the moving picture is compressed and stored.

Typically, moving picture data is recorded regardless of compression, and the recorded moving picture data is updated in a repeat mode. That is, the repeat mode means that when recording moving image data in a storage medium, the moving image data of the space in which the oldest moving image data is recorded among the spaces in which the existing moving image data is recorded when there is no more empty space to record on the storage medium. This operation means deleting and deleting new video data in this space.

1A and 1B are schematic diagrams illustrating a data structure of a storage medium when updating moving picture data in a repeat mode according to the related art.

1A and 1B, a moving image having a plurality of frames is sequentially recorded on the storage medium. That is, the frames from the 1-1 st frame 101 to the 1 st n frame 104 are recorded in the storage medium. When new moving picture data is to be recorded and updated through the storage medium, deletion and recording are repeated from the first frame of the previously recorded moving picture. That is, the first-first frame 101 is deleted and the second-first frame 201, which is the first frame of new video data, is recorded. Also, the 1-2 frame 102 is deleted and the second frame 202 is recorded. Subsequently, the same operation is performed on the 1-3 frame 103. The above operation is repeatedly performed sequentially until the recording of the new moving image data is completed.

FIG. 2 is a flowchart for explaining update of moving picture data in the repeat mode shown in FIGS. 1A and 1B.

Referring to FIG. 2, first, it is checked whether recording of image data is performed in the repeat mode (S100). The checking of the repeat mode may be variously performed according to a storage medium. If the storage medium is a hard disk, it is performed in a hard disk drive or the like, and in the case of a nonvolatile memory device, the storage medium can be made in a control device or the like for accessing the disk.

In the repeat mode, an integer n for distinguishing a frame is set to 1 (S110). In addition, the first-n frame recorded on the storage medium is deleted (S120). That is, the first-first frame is deleted, and the second-first frame is recorded at the position where the first-first frame is deleted (S130). The video data is updated in the storage medium by the recording of the second-1 frame.

Subsequently, it is checked whether a repeat record is to be continuously performed (S140). If repeat recording is continued, the integer n is set to n + 1 (S150). In other words, the integer n is incremented by 1 each time the loop is performed.

If the repeat record operation is terminated, updating of the image data is stopped, and an operation of replacing or adding a storage medium is performed (S160).

As described above, when the image data is updated according to the prior art, the image data previously recorded by the newly recorded image data is deleted, and the deleted image data is completely lost. Therefore, when information about previous image data is requested, there is a disadvantage that there is no way to recover it.

SUMMARY OF THE INVENTION A first object of the present invention for solving the above problems is to provide a storage medium having a data structure capable of recording new image data without completely deleting previous image data when updating image data in a repeat mode.

A second object of the present invention is to provide a method of updating image data of a storage medium used to achieve the first object.

The present invention for achieving the first object, the first image data consisting of a plurality of frames; And second image data including frames recorded between the frames of the first image data, wherein the frames of the second image data are deleted by even, odd, or integer multiples of the first image data. It provides a storage medium, characterized in that stored in a stored location.

In addition, the first object of the present invention, the first image data consisting of blocks having frames; And second image data including blocks recorded between blocks of the first image data, wherein the blocks of the second image data are deleted by even, odd, or integer multiples of the first image data. It can also be achieved through the provision of a storage medium, characterized in that it is stored at the location.

In addition, the present invention for achieving the second object, the step of confirming whether to execute a repeat mode for recording a new second image data in the position where the first image data is recorded; Deleting odd-numbered, even-numbered, or integer-numbered frames of the first image data; And recording a continuous frame of the second image data at a position where the frame of the first image data is deleted.

In addition, the second object of the present invention is to determine whether to execute a repeat mode for recording new second image data at a position where the first image data is recorded; Setting an integer identifying a video block of the first video data to be deleted first when executing the repeat mode; Deleting an odd-numbered, even-numbered, or integer multiple of the image block of the first image data; Recording a continuous image block of the second image data at a position where the image block of the first image data is deleted; And determining whether or not the recording of the second image data is completed.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First embodiment

3 is a schematic diagram showing a data structure of a storage medium when updating moving picture data in a repeat mode according to the first embodiment of the present invention.

Referring to FIG. 3, the first image data, which is the previous image data, is composed of a plurality of frames. That is, it is composed of the 1-1 st frame 311, the 1-2 frames to the first-n frame (315). In addition, even-numbered frames are deleted, and at the deleted position, second image data, which is new image data, is recorded in the storage medium. That is, the second-first frame 321 is recorded at the position where the 1-2 frames are deleted, and the second-second frame 322 is recorded at the position where the 1-4 frames are deleted. The 2-1 th frame 321 and the 2-2 th frame 322 constitute second image data and are set to consecutive frames.

Accordingly, the first-first frame 311, the first-third frame 313, and the like, which are odd-numbered frames of the first image data, remain on the storage medium, and the first frame of the first image data has been deleted. 2 Image data is recorded.

Also, in the present embodiment, odd-numbered frames may be deleted from the first image data, and second image data may be recorded at the deleted position.

As described above, the previous image data is not all deleted, only even-numbered frames or odd-numbered frames are deleted. In addition, frames of integer multiples are regularly deleted. That is, frames having regular intervals such as the first frame, the fourth frame, and the seventh frame may be deleted. New image data is recorded at the positions of the deleted frames.

That is, successive new image data are recorded alternately at the position where the previous image data is stored. Therefore, even if new image data is stored, the previous image data is not completely deleted, and half of the frames constituting the previous image data remain.

In addition, the storage medium is a nonvolatile memory represented by a hard disk or flash memory device.

FIG. 4 is a flowchart illustrating a method of updating image data in the storage medium shown in FIG. 3 according to the first embodiment of the present invention.

Referring to FIG. 4, first, it is checked whether recording of image data is performed in the repeat mode (S200). The checking of the repeat mode may be variously performed according to a storage medium. If the storage medium is a hard disk, it is performed in a hard disk drive or the like, and in the case of a nonvolatile memory device, the storage medium can be made in a control device or the like for accessing the disk.

In the repeat mode, an integer n for distinguishing a frame is set to 2 (S210). In addition, the first-n frame recorded on the storage medium is deleted (S220). That is, the 1-2 frames are deleted, and the 2-1 frame, which is new image data, is recorded at the position where the 1-2 frames are deleted (S230). The video data is updated in the storage medium by the recording of the second-1 frame.

If the frame to be deleted is an odd frame, the integer n for distinguishing the first frame is set to one.

Subsequently, it is checked whether recording of new video data is completed (S240). That is, a determination is made as to whether to update the frame recorded on the storage medium further. If there is a frame to be additionally updated, the integer n for distinguishing the frame is set to n + 2. In other words, the integer n that distinguishes frames increases by two each time the loop is performed.

Since n is initially set to 2, n is set to 4 when a new frame is updated. Also, the 1-4 frames are deleted, and the 2-2 frames, which are new image data, are recorded at the deleted positions. This repetitive operation proceeds until the recording of new video data is completed.

When recording of new video data is completed, it is determined whether another video data is to be updated (S260). That is, when a part of the first image data is deleted and the recording of the second image data is completed, it is determined whether to record new third image data.

When a repeat record for updating with new third video data is to be performed, an initial value of a frame is set again, and an operation of repeatedly deleting and recording is performed.

If the repeat record operation is terminated, updating of the video data is stopped, and an operation of replacing or adding a storage medium is performed.

In FIG. 4, even-numbered frames of the first image data are deleted, and new second image data is recorded at the deleted position. However, according to the exemplary embodiment, odd-numbered frames or three or more frames of the first image data are recorded. Frames are regularly deleted at intervals, and new image data may be recorded at the deleted positions.

Second embodiment

5 is a schematic diagram showing a data structure of a storage medium when updating moving picture data in a repeat mode according to a second embodiment of the present invention.

Referring to FIG. 5, image data is stored in units of blocks. That is, they are stored in the storage medium in units of blocks separated by a certain time. Storing image data in units of blocks is implemented by dividing the data at regular time intervals, specifying blocks for the divided data, and storing the defined blocks in the storage medium.

Therefore, the first image data is divided into a plurality of blocks and sequentially recorded in the storage medium. In addition, each block includes a plurality of frames. The first image data is composed of n consecutive image blocks, such as a 1-1 image block 411 and a 1-2 image block.

Subsequently, when the repeat mode is performed on the storage medium on which the first image data is recorded so that the second image data, which is new image data, is recorded at the position where the first image data is stored, the interval of the odd numbered block, the even number, or the integer multiple is set. The image data of the excitation block is deleted, and the second image data is recorded at the deleted position. For example, when new second image data is recorded in the even-numbered block, the 1-2 video block is deleted, and the 2-1 video block 421 is recorded at the deleted position. In addition, the 1-4 image block is deleted, and the 2-2 image block 422 is recorded at the deleted position. The 2-1 image block 421 and the 2-2 image block 422 are image blocks constituting second image data, and are composed of a plurality of frames that are continuous in time.

Accordingly, the first-first image block 411, the first-three image block 413, and the like, which are odd-numbered blocks of the first image data, remain in the storage medium, and the even-numbered blocks of the deleted first image data remain. Second image data is recorded. In addition, an operation of recording consecutive blocks of new second image data at the erased and deleted positions of the odd-numbered blocks of the first image data may be performed.

6 is a flowchart illustrating a method of updating image data blocked in the storage medium shown in FIG. 5 according to the second embodiment of the present invention.

Referring to FIG. 6, first, it is checked whether recording of image data is performed in the repeat mode (S300). The checking of the repeat mode may be variously performed according to a storage medium. If the storage medium is a hard disk, it is performed in a hard disk drive or the like, and in the case of a nonvolatile memory device, the storage medium can be made in a control device or the like for accessing the disk.

In the repeat mode, an integer n for distinguishing a block is set to 2 (S310). In addition, the first-n image block recorded in the storage medium is deleted (S320). That is, the 1-2 video block is deleted, and the 2-1 video block, which is new image data, is recorded at the position where the 1-2 video block is deleted (S330). Video data is updated in the storage medium by recording the 2-1 video block. That is, all the frames in the 1-2 video block are deleted, and the frames included in the 2-1 video block are recorded.

Next, it is checked whether recording of new video data is completed (S340). That is, a determination is made as to whether to update the video block additionally. If there is an image block to be additionally updated, the integer n for distinguishing the block is set to n + 2. In other words, the integer n that distinguishes the block is incremented by two each time the loop is performed.

Since n is initially set to 2, n is set to 4 when a new block is updated. Also, the 1-4 image block is deleted, and the 2-2 image block, which is new image data, is recorded at the deleted position. This repetitive operation proceeds until the recording of new video data is completed. In addition, the 2-1st image block and the 2-2th image block of the newly recorded second image data are composed of a plurality of frames that are continuous in time.

When recording of new video data is completed, it is determined whether another video data is to be updated (S360). That is, when a part of the first image data is deleted and the recording of the second image data is completed, it is determined whether to record new third image data.

When a repeat record for updating with new third video data is to be performed, an initial value of the block is set again, and the operation of repeatedly deleting and recording is performed.

In addition, in FIG. 6, even-numbered image blocks are deleted, and successive image blocks of new image data are recorded at the deleted positions. However, odd-numbered image blocks or images having an interval of 3 or more according to an exemplary embodiment. The blocks may be deleted, and successive image blocks of new image data may be recorded at the deleted position.

Therefore, instead of sequentially deleting already recorded image data from the beginning for recording new image data, the previous image data is partially left and new image data is recorded at the partially deleted position. By alternately recording different image data, some of the already recorded image data can be used, and new image data can also be recorded.

According to the present invention as described above, previously recorded image data is not completely deleted in the repeat mode of deleting already recorded image data and recording new image data at the deleted position. In addition, new image data is recorded at positions where the previous image data is alternately deleted. Therefore, even in the repeat mode, previously recorded image data remains, and when information on previously recorded image data is required, it can be provided to the user.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

Claims (12)

First image data composed of a plurality of frames; And Second image data composed of frames recorded between the frames of the first image data, And the frames of the second image data are stored at positions where frames having an even number, an odd number, or three or more intervals of the first image data are deleted. The storage medium of claim 1, wherein the first image data or the second image data is a moving image. The storage medium of claim 2, wherein the storage medium is a hard disk or a flash memory. The method of claim 1, wherein consecutive frames of the second image data are sequentially recorded at positions where even-numbered frames, odd-numbered frames, or frames having an interval of 3 or more of the first image data are deleted. Storage media. First image data composed of blocks having frames; And Second image data composed of blocks recorded between blocks of the first image data, And the blocks of the second image data are stored at positions where blocks having an even number, an odd number, or three or more intervals of the first image data are deleted. The storage medium of claim 5, wherein the blocks of the first image data and the blocks of the second image data are divided at regular time intervals. Confirming whether to execute a repeat mode in which new second image data is recorded at a position where the first image data is recorded; Deleting frames having an odd numbered, even numbered, or three or more intervals of the first image data; And And recording a continuous frame of the second image data at a position where the frame of the first image data is deleted. 8. The method of claim 7, further comprising, after confirming whether to execute the repeat mode, setting an integer for distinguishing a frame to be deleted first. The method of claim 8, further comprising determining whether or not the recording of the second image data is completed after recording the frame of the second image data. 10. The method of claim 9, further comprising increasing an integer by which the frame is distinguished by two when recording of the second image data is not completed. Confirming whether to execute a repeat mode in which new second image data is recorded at a position where the first image data is recorded; Setting an integer identifying a video block of the first video data to be deleted first when executing the repeat mode Deleting image blocks having an odd numbered, even numbered, or three or more intervals of the first image data; Recording a continuous image block of the second image data at a position where the image block of the first image data is deleted; And And determining whether recording of the second image data is completed. 12. The method of claim 11, further comprising increasing an integer by which the image block is distinguished by two when recording of the second image data is not completed.

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