KR100196848B1 - Apparatus for compensating error in image decoder - Google Patents

Abstract

The present invention relates to an error compensator in an image decoder in which continuity between screen blocks of a reconstructed image can be accurately implemented. To solve this problem, the image data, which is encoded and input, is reconstructed by the decoder 100 in units of screen blocks. An image decoder comprising: an error detector (200) for outputting the current screen block and error information based on a linear predicted pixel value of a current screen block provided from a decoder (100) and a pixel value of an adjacent screen block; An error correction unit 300 for replacing the current screen block with the same position screen block of the previous video signal and outputting the same based on the error information of the error detection unit 200; By including the display device 400 for displaying the corrected screen block output from the error correction unit 300, there is an effect that the continuity between the screen blocks of the reconstructed image can be accurately implemented.

Description

Error Compensator in Video Decoder

1 is a block diagram showing an error compensator in an image decoder according to the present invention.

2A to 2C are diagrams illustrating a current screen block and an adjacent screen block for explaining FIG.

* Explanation of symbols for main parts of the drawings

100: decoder 200: error detection unit

300: error correction 400: display device

The present invention relates to an image decoder, and more particularly, to an error compensator in an image decoder in which continuity between screen blocks of a reconstructed image can be accurately realized.

In general, when a video signal composed of a series of image frames is represented in a digital form, a considerable amount of data must be transmitted, particularly in the case of a high definition television (hereinafter referred to as HDTV).

However, since the usable frequency range of a conventional transmission channel is limited, in order to transmit a large amount of digital data, it is necessary to compress the transmitted data and reduce the amount thereof.

Therefore, among the various compression schemes introduced, hybrid coding techniques combining stochastic coding and temporal and spatial compression are known to be the most efficient.

Most hybrid coding techniques use motion-compensated DCPM (Differential Pulse Code Modulation), 2-D Discrete Cosine Transform (DCT), quantization of DCT coefficients, entropy protector, and so on.

The motion compensation DPCM determines a motion of an object between a current frame and a previous frame and predicts the current frame according to the motion of the object to generate a differential signal representing the difference between the current frame and the predicted value.

That is, the motion compensation DPCM predicts the current frame from the previous frame according to the motion of the object estimated between the current frame and the previous frame, and the predicted motion displacement is a two-dimensional motion vector representing the displacement between the previous frame and the current frame. It can be represented as.

For example, if the optimal block motion information determined by comparing the screen block of the current frame with the screen blocks of the previous frame by the block unit motion estimation technique of the video encoder is provided to the video decoder, the video decoder is transmitted from the video encoder. Based on the motion displacement information, the original image is restored and output to the display apparatus.

The boundary matching algorithm (BMA) or the sliding matching algorithm (Side) is used to determine whether a screen block restored to the original image is appropriate based on the motion displacement information, or to find an area damaged during the transmission process. A boundary comparison algorithm of screen blocks called Matching Algorithm (SMA) has been used.

For example, when the slide matching algorithm is described, the size of the video screen block is referred to as N × N, and the reconstructed pixel value of the nth frame is represented by f _R (x, y, n).

Where (x, y) represents the spatial coordinate. Next, the amount of change C _A , C _L , and C _B at the boundary between the current screen block and the top (C _A ), left (C _L ), and bottom (C _B ) screen blocks of the screen block is defined as follows. do.

The C _A represents the amount of change in the pixel value of the boundary portion between the current screen block and the screen block located above the current screen block (C _A ), that is, the pixel value of the current screen block located at the boundary portion and the current screen block. _A value obtained by subtracting the pixel value located above the upper portion C _A by one-to-one and then adding up the subtracted value.

The C _L refers to the amount of change in the pixel value of the boundary portion between the current screen block and the screen block located to the left (C _L ) of the current screen block. The pixel value located on the left side C _L is subtracted one-to-one, and the sum of the subtracted values.

The C _B is the current picture block and its means the amount of change of the current screen, block bottom perimeter of the pixel between the screen block in the (C _B) values, that is, the pixel values of the current screen, block located at the boundary between the current screen, block It means a value including the subtracted value after subtracting the pixel value positioned below the lower portion C _B by one to one.

That is, in SMA, when the change amount C = C _A + C _B + C _L of the boundary portion is larger than a predetermined threshold, the SMA determines that the current screen block is not continuity with the adjacent screen block.

On the contrary, when the change amount C = C _A + C _L + C _B of the boundary portion is smaller than a predetermined threshold, it is determined that the current screen block is continuous with the adjacent screen block.

However, when the edge component is included, since the pixel value of the image changes abruptly, the continuity between the current screen block and the adjacent screen blocks cannot be accurately determined.

Accordingly, the present invention has been made to solve the above disadvantages, and an object of the present invention is to provide an image decoder capable of accurately reconstructing a damaged image to an original image by accurately determining continuity between adjacent screen blocks in a digital image. An error compensator is provided.

According to the present invention for achieving the above object, in the image decoder for restoring the image data is encrypted and input by the decoder 100 in the unit of the screen block, the linearity of the current screen block provided from the decoder 100 An error detector (200) for outputting the current screen block and error information based on a predicted pixel value and a pixel value of an adjacent screen block; An error correction unit 300 for replacing the current screen block with the same position screen block of the previous video signal and outputting the same based on the error information of the error detection unit 200; It characterized in that it comprises a display device 400 for displaying the corrected screen block output from the error correction unit (300).

Hereinafter, the present invention will be described in detail with reference to the illustrated drawings.

1 is a block diagram illustrating an error compensator for an image decoder according to the present invention.

Referring to FIG. 1, an error compensator of the present invention includes a decoder 100, an error detector 200, an error compensator 300, and a display device 400.

The decoder 100 is configured to decode (decode and restore) bitstream data that is encoded and input from an image encoder to be provided to an error detector 200 to be described later. The decoder 100 includes a variable length decoder (VLD), An inverse quantizer (IQ), an inverse DCT, a subtractor, a motion compensator and a frame memory.

The error detection unit 200 displays the current screen block and the error information, which will be described later, based on the linearly predicted pixel value of the current screen block provided from the decoder 100 and the display value 400. Is configured to output

In addition, the equation applied for linear prediction of the error detector 200 is as follows.

That is, when C 'obtained by adding C' _A, C ' _{L, and} C' _B, obtained above is larger than a preset threshold, an error information signal is generated that indicates that the current screen block is not continuity with an adjacent screen block. will be.

C ' _A, C' _L, C ' _B, are linear predicted values of pixel values located at the top, left, and bottom of the boundary of the screen block adjacent to the current screen block, and f _R is the restored current screen block. F _P denotes a linear predicted pixel with respect to a predetermined pixel value of the current screen block.

The error correction unit 300 may correct the current screen block in which the error occurs by restoring the current screen block to the previous screen block stored at the same position of the previous image based on the error information of the error detector 200. The error correction unit 300 includes a frame memory for storing a previous frame.

The display device 400 is configured to display the corrected screen block output from the error correction unit 300.

The present invention configured as described above will be described in detail with reference to Examples. First, the image encoder converts a subject into digital, compresses the converted digital signal, and sends the converted digital signal to the decoder 100 of the image decoder.

Accordingly, the decoder 100 of the image decoder restores the image data compressed from the image encoder and input into the bitstream, and then provides the image data to the error detector 200.

Referring to FIG. 2A, the error detector 200 obtains a linear predicted pixel value between a current screen block and a screen block adjacent to the top of the screen block.

That is, the linear prediction value X _AP located above the predetermined pixel value B of the current screen block is; X _AP = B + {(A + B + C) / 3- (D + E + F) / 3}, and A, C, D, E, and F are the predetermined pixel values of the current screen block. It becomes the peripheral pixel value of (B).

If the obtained linear prediction value (X _AP ) is applied to all pixels located above the current screen block, the linear prediction values for the pixels located above the current screen block can be obtained. .

That is, C ' _A means a linear predicted value of pixel values located above the boundary of the screen block adjacent to the current screen block, and f _R is a pixel located above the current screen block; f _P means a linear predicted pixel with respect to the pixel value located above the current screen block.

In addition, referring to FIG. 2B, the error detection unit 200 obtains a linear predicted pixel value between the current screen block and the screen block adjacent to the left side of the screen block.

The linear prediction value X _LP located to the left of the predetermined pixel value B of the current screen block is; X _LP = B + {(A + B + C) / 3- (D + E + F) / 3}, and A, C, D, E, F are the predetermined pixel values of the current screen block. It becomes the peripheral pixel value of (B).

If the obtained linear prediction value X _LP is applied to all pixels located on the left side of the current screen block, the linear prediction value for the pixels located on the left side of the current screen block can be obtained therefrom.

That is, C ' _L means a linear predicted value of pixel values located on the left side of the boundary of the screen block adjacent to the current screen block, and f _R is a pixel located on the left side of the current screen block; f _P means a linear predicted pixel with respect to the pixel value located on the left side of the current screen block.

Referring to FIG. 2C, the error detector 200 obtains a linear predicted pixel value between the current screen block and a screen block adjacent to the bottom of the screen block.

The linear prediction value X _BP located below the predetermined pixel value B of the current screen block is; X _BP = B + {(A + B + C) / 3- (D + E + F) / 3}, and A, C, D, E, F are the predetermined pixel values of the current screen block. It becomes the peripheral pixel value of (B).

When the obtained linear prediction value X _BP is applied to all the pixels located below the current screen block, the linear prediction values for the pixels located below the current screen block can be obtained.

That is, C ′ _B means a linear predicted value of pixel values located below the boundary portion of the screen block adjacent to the current screen block, and f _R is a pixel located below the current screen block; f _P means a linear predicted pixel with respect to a pixel value located below the current screen block.

When C 'obtained by adding C' _A, C ' _{L, and} C' _B obtained as described above is larger than a preset threshold, an error information signal indicating that the current screen block is not continuity with an adjacent screen block is received from the error detection unit 200. The error correction unit 300 is provided.

The error correction unit 300 restores the current screen block to the previous screen block stored in the same position of the previous image based on the error information of the error detection unit 200, corrects the current screen block in which the error occurs, and then displays it. Output to the device 400.

Therefore, the display apparatus 400 displays the corrected screen block output from the error correction unit 300, and the screen block determined to have no error is output to the display apparatus 400 as it is.

As described above, the present invention has an effect of restoring a damaged part due to an error in a digital image processing process.

Claims (3)

A video decoder for reconstructing coded and input image data in units of picture blocks by the decoder 100, wherein the decoder 100 performs a linear predicted pixel value of the current screen block provided from the decoder 100 and a pixel value of an adjacent picture block. An error detector for outputting the current screen block and error information based on the error detection unit; An error correction unit 300 for replacing the current screen block with the same position screen block of a previous video signal and outputting the same based on the error information of the error detection unit 200; And a display device (400) for displaying the corrected screen block output from the error compensator (300). According to claim 1, The equation applied for linear prediction of the error detector 200, Is the same as Where C ' _A, C' _{L and} C ' _B are linear predicted values of pixel values located at the top, left, and bottom of the boundary of the screen block adjacent to the current screen block; f _R is the pixel of the restored current screen block; and f _P is a linear predicted value with respect to a predetermined pixel value of the current screen block. When C 'obtained by adding C' _{A and} C ' _L C' _B is larger than a preset threshold, an error compensation signal is provided that provides an error signal that the current screen block is not continuous with an adjacent screen block. Device.