KR100805016B1 - Apparatus and method for correcting an error of picture - Google Patents

Abstract

An apparatus and a method for correcting an error of an image are provided to divide a reference image frame into n slices, store the divided slices in an error correction buffer and correct the error by using data stored in the error correction buffer if an error-generated slice is present within the image, thereby preventing a user from watching an error image as much as possible. An error check module(102) divides an image, inputted from the outside, into n number of slices and checks whether errors are generated in each slice. A reference image extraction module(104) receives a reference image frame inputted at preset time intervals, divides the received reference image frame into n number of slices, assigns a reference value to each slice, stores the reference value and each slice of the reference image frame in an error correction buffer(108), and updates the error correction buffer by using the stored reference value and each slice whenever the reference image frame is inputted. If an error occurs in an arbitrary slice of an arbitrary image, an error correction module(106) extracts a slice, corresponding to a reference value corresponding to the slice where the error occurs, from the error correction buffer and corrects the error-occurred slice by using the extracted slice.

Description

Image error correction device and method {APPARATUS AND METHOD FOR CORRECTING AN ERROR OF PICTURE}

1 is a view for explaining a conventional error correction process,

2 is an exemplary view for explaining a problem in the conventional error correction process,

3 is a block diagram illustrating an image error correction apparatus according to an exemplary embodiment of the present invention.

4 is a flowchart illustrating a process of storing a reference image frame by an error correction apparatus according to an exemplary embodiment of the present invention.

5 is a flowchart illustrating a process of correcting an error of an image in which an error occurs according to the present invention.

<Description of the code | symbol about the principal part of drawing>

102: error check module 104: reference image extraction module

106: error correction module 108: error correction buffer

110: decoding module 112: control module

The present invention relates to image error correction, and more particularly, to an image error correction apparatus and method for correcting an error using a slice of an error generated slice of a reference image frame.

In general, moving image data has a very large amount of information, so it is very difficult to record or transmit it as it is. For this reason, an encoding technique for compressing the amount of data is essential. Until now, international standards such as MPEG-1, 2, and 4 have been defined by ISO, and have been applied to DVD, digital broadcasting, and image transmission in next-generation mobile phones.

Recently, H.264 is being researched as an international standard, and H.264 estimates motion from an already encoded image frame, generates a prediction signal, and encodes a tram signal by performing discrete cosine transform (DCT) encoding. It is based on a technique called motion compensation + DCT.

Meanwhile, for video decoding, video is always decoded by performing a motion vector, a motion compensation process, etc. In particular, a motion compensation is performed during decoding, and a decoding process is performed accordingly.

In the decoding process, an image, which is a reference, is stored in a memory in the decoder and is decodable by itself. That is, video compression is performed under the premise that the next video is decoded using the difference value in the reference video, and if there is no video serving as the reference, decoding itself becomes impossible.

For example, as shown in FIG. 1, if an error occurs in a reference image value on the premise that an image of n-4 among blocks consisting of n images becomes a reference in a block, as shown in FIG. 2. An error will occur in that part of the reference image.

That is, since a video decoder generally performs decoding by referring to n-4 pictures when decoding n pictures, there is a problem in that n pictures are not properly decoded when an error occurs in the n-4 reference pictures. .

In addition, there is a problem that the user must watch the disconnected image for a predetermined time due to this problem.

SUMMARY OF THE INVENTION An object of the present invention is to solve such a problem of the prior art, and divides a reference image frame into n slices and stores the same in an error correction buffer. The present invention provides an image error correction apparatus and method that can prevent a user from viewing an error image as much as possible by correcting the data.

In order to achieve the above object, the present invention provides an error check module for dividing an image input from the outside into n slices (n≥2, n is a natural number) and checking whether an error occurs for each slice; Receiving reference image frames input at predetermined time intervals, dividing the data into n slices, assigning reference values to each slice, storing the reference value and each slice of the reference image frame in an error correction buffer, and A reference image extraction module for updating the error correction buffer by using an image frame whenever the image frame is input, and an error is generated when any error is generated in any slice of an image when the error check module checks whether an error occurs. The slice corresponding to the reference value corresponding to the slice is added to the error correction buffer. And includes an error correction module for correcting the error occurs, the slice using the extracted slice.

According to another aspect of the present invention, a) a step of receiving an image from the outside, and b) n (n≥2, n is a natural number) of the reference picture frame when the image input from the outside is a reference picture frame. Dividing into slices and assigning a reference value to each slice; c) storing the reference value and the slice of the reference image frame in an error correction buffer and decoding and outputting the same; and d) the image input from the outside. If it is not the reference image frame, dividing the image into n slices and checking whether an error has occurred for each slice; and e) if there is an error slice in the n slices as a result of the check Extracting, from the error correction buffer, a slice corresponding to a reference value corresponding to the error generated slice; Correcting the error-produced slice using the extracted slice, and decoding the output slice.

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

3 is a block diagram illustrating an image error correction apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the image error correction apparatus according to the present invention includes an error check module 102, a reference image extraction module 104, an error correction module 106, an error correction buffer 108, and a decoding module 110. And a control module 112 for overall control of each module.

The error checking module 102 receives an image from the outside and divides the slice into n slices (n ≧ 2, where n is a natural number) and checks whether an error occurs for each slice.

The image received from the outside includes an I-Picture (Intra-Picture) as a reference image frame.

The reference image extraction module 104 extracts a reference image frame among images input from the outside, divides it into n slices, gives a reference value to each slice, and stores the reference image frame in the error correction buffer 108. Each time, the error correction buffer 108 is updated using each slice of the input reference picture frame and a reference value corresponding thereto.

Meanwhile, the reference image extraction module 104 extracts a motion vector by comparing each slice of the reference image frame and each slice of the reference image frame previously stored in the error correction buffer 108, and extracts the extracted motion vector into an error. Store in the correction buffer 108.

Also, when an error occurs in the reference picture frame, the reference image extraction module 104 corrects the error by using the previous picture frame, that is, corrects the error by using the previous picture frame in the part where the error occurs in the reference picture frame. The data stored in the error correction buffer 108 is then updated.

When the error check module 102 checks whether an error occurs in the error check module 102, when an error occurs in any slice of an image, the error correction module 106 selects a slice corresponding to the reference value of the error-produced slice in the error correction buffer 108. The extracted slice is corrected and the error slice is corrected and output to the decoding module 110. Accordingly, the decoding module 110 decodes the input image and displays the image on an external display device (not shown).

As described above, the error-produced slice is corrected using the slice stored in the error correction buffer 108 and then output, thereby preventing the user from viewing the error image as much as possible.

The operation of the image error correction apparatus having the above configuration will be described with reference to FIGS. 4 to 5.

4 is a flowchart illustrating a process of storing a reference image frame by an error correction apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 4, when a reference image frame is input from the outside (S200), the reference image extraction module 104 checks whether an error exists in the reference image frame after receiving the reference image frame (S202).

If an error exists in the reference picture frame as a result of checking in step S202, the reference picture extraction module 104 corrects the error using the previous picture frame (S204), and then divides the error corrected reference picture frame into n slices. After that, a random reference value is assigned to each slice (S206).

Thereafter, the reference image extraction module 104 determines whether there is a reference value corresponding to data, that is, a reference image frame previously input, and each slice in the error correction buffer 108 (S208).

As a result of the determination in step S208, when data exists in the error correction buffer 108, the reference image extraction module 104 compares each slice of the currently input reference image frame with each slice previously stored in the error correction buffer 108. The motion vector is calculated and stored in the error correction buffer 108 (S210), and the error correction buffer 108 is updated using the reference value calculated in step S206 and each slice of the reference image frame (S212).

On the other hand, if there is no data in the error correction buffer 108 as a result of the determination in step S208, the reference image extraction module 104 stores each slice of the reference value and the reference image frame calculated in step S206 in the error correction buffer 108. Save it (S214).

In addition, if no error exists as a result of the determination in step S202, the flow advances to step S206 to perform subsequent steps.

A process of correcting an error generated image using data stored in the error correction buffer 108 through the above process will be described with reference to FIG. 5.

5 is a flowchart illustrating a process of correcting an error of an image in which an error occurs according to the present invention.

First, referring to FIG. 5, when an image is input from the outside (S300), the error check module 102 divides the image into n slices and then determines whether an error exists for each slice (S302 and S304). In this case, the error check module 102 divides the image into slices by the same number as that of the reference image extraction module 104.

As a result of the determination in step S304, if an error exists, an image is provided to the error correction module 106, and the error correction module 106 extracts the slice corresponding to the slice in which the error has occurred from the error correction buffer 108 and then extracts it. By replacing the error-produced slice with the slice, the error-produced slice in the image is corrected and then output to the decoding module 110 (S306, S308). In this case, the error correction module 106 searches the error correction buffer 108 based on the reference value corresponding to the slice in which the error has occurred and extracts a slice corresponding to the slice in which the error has occurred.

Thereafter, the decoding module 110 decodes the error corrected image provided from the error correction module 106 and outputs the decoded image to the external display device (S310).

On the other hand, as a result of the determination in step S304, if no error exists, the image is provided to the decoding module 110, the decoding module 110 performs the step S310, that is to decode the image and output it to the external display device.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, the present invention divides a reference picture frame into n slices and stores the same in an error correction buffer, and if there is an error generated slice in the image, corrects the data using the data stored in the error correction buffer. You can avoid seeing the error picture as much as possible.

Claims (6)

An error check module for dividing an image input from the outside into n slices (n ≧ 2, n is a natural number) and checking whether an error occurs for each slice; After receiving reference image frames input at predetermined time intervals and dividing them into n slices, the reference values are assigned to each slice, the reference value and each slice of the reference image frame are stored in an error correction buffer, and the reference image A reference image extraction module for updating the error correction buffer by using the frame whenever a frame is input; When an error occurs in any slice of an image when the error check module checks whether an error occurs, a slice corresponding to a reference value corresponding to the error generated slice is extracted from the error correction buffer, and the extracted slice is extracted. An error correction module that corrects the error-prone slice Image error correction apparatus comprising a. The method of claim 1, The reference image extraction module, And a motion vector is calculated and stored in the error correction buffer by comparing each slice previously stored in the error correction buffer and each slice of the received reference image frame when the error correction buffer is updated. The method of claim 1, The reference image extraction module, And an error occurs in the reference picture frame, wherein the error of the reference picture frame is corrected using the picture frame received before the reference picture frame. a) receiving an image from the outside, b) dividing the reference image frame into n slices (n ≧ 2, n is a natural number) and assigning a reference value to each slice when the image input from the outside is a reference image frame; c) storing the reference value and the slice of the reference image frame in an error correction buffer, decoding and outputting the same; d) checking whether an error occurs for each slice after dividing the image into n slices if the image input from the outside is not a reference image frame; e) extracting, from the error correction buffer, a slice corresponding to a reference value corresponding to the error generated slice when there are error generated slices in the n slices; f) correcting the error-produced slice using the extracted slice and then decoding and outputting Image error correction method comprising a. The method of claim 4, wherein The error correction method, Determining whether data exists in the error correction buffer after assigning a reference value to each slice of the reference image frame; If the data exists, the step d) is performed after calculating a motion vector and storing the motion vector in the error correction buffer by comparing each slice previously stored in the error correction buffer with each slice of the reference image frame. Video error correction method. The method of claim 4, wherein In step b), when an error occurs in the reference picture frame, n slices of the error-corrected reference picture frame are corrected after correcting an error of the reference picture frame using the picture frame received before the reference picture frame. And a reference value is assigned to each slice.

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