KR20110002121A - Image processing device for minimizing distortion in transferred image and image processing methd thereof - Google Patents

Abstract

PURPOSE: An image processing device for minimizing distortion in a transferred image and an image processing method thereof are provided to transfer an actual image as a transmission image in a transmission block if a restored image has an error which has larger error range than the actual image. CONSTITUTION: A compression restoring block(100) performs the compression and restoration of an actual image, and a distortion processing block(200) restores an encoded and compressed image into a compression restored image. The distortion processing block generates a storage image by comparing the compression and restoration image with the actual image. An overdrive block(300) provides a compensated driving image by the over driving of a present restored image. A transmission block(400) selectively provides the compensation driving image as the transmission image.

Description

IMAGE PROCESSING DEVICE FOR MINIMIZING DISTORTION IN TRANSFERRED IMAGE AND IMAGE PROCESSING METHD THEREOF}

In order to more fully understand the drawings used in the detailed description of the invention, a brief description of each drawing is provided.

1 is a block diagram illustrating an image processing apparatus according to an embodiment of the present invention.

FIG. 2 is a view specifically illustrating a compression unit of FIG. 1.

3 is a view illustrating in detail the distortion processor of FIG. 1.

4 is a view illustrating in detail the previous image restoration unit of FIG. 1.

FIG. 5 is a diagram illustrating the overdrive block of FIG. 1 in detail.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing apparatus and an image processing method thereof, and more particularly, to an image processing apparatus and an image processing method thereof for minimizing distortion of a transmission image while transmitting an image using a compression method.

In general, data transmitted from an image processing apparatus includes information representing a luminance component of an image and information representing a chroma component of an image. Among them, the luminance component is an area sensitively reacting to the human eye, and the color component is an area that is relatively insensitive to the luminance component. Various transmission methods have been proposed to reduce the amount of data in an image by appropriately compressing and transmitting color component information by using the characteristics of the human body. One such transmission method is a compression method. The compression method is a method of compressing and transmitting a transmitted image, and restoring and displaying the image.

However, a case in which the transmitted image transmitted through the compressor method is significantly distorted from the actual image may occur. Such distortion of the image acts as a factor of degrading the quality of the displayed image.

Accordingly, there is a need for an image processing apparatus and an image processing method for reducing distortion of a transmission image while transmitting an image by a compressor method.

SUMMARY OF THE INVENTION An object of the present invention is to provide an image processing apparatus and an image processing method thereof for minimizing distortion of a transmitted image while transmitting an image by a compressor method.

One aspect of the present invention for achieving the above technical problem relates to an image processing apparatus for receiving a real image and generating a transmission image. The image processing apparatus of the present invention includes: a compression restoring block for encoding the real image and compressing the actual image into an encoded current image and then restoring the encoded current image to a current restored image; A distortion processing block for restoring an encoded compressed image according to the encoding current image to a compressed restored image, and generating a stored image by comparing the compressed restored image with the actual image, wherein the stored image is the compressed restored image for the actual image. The distortion processing block determined according to a predetermined identification code when the distortion of the image is larger than a predetermined error range; An overdrive block for overdriving the current restored image to provide a corrected driving image; And a transmission block for selectively providing the corrected driving image as the transmission image. When the stored image is determined to be in accordance with the identification code, the transmission block provides the actual image as the transmission image.

One aspect of the present invention for achieving the above technical problem relates to an image processing method of an image processing apparatus for receiving a real image and generating a transmission image. The image processing method of the present invention comprises the steps of: A) after encoding the actual image and compressing the encoded current image, restoring and providing the encoded current image as a current restored image; B) restoring an encoded compressed image according to the encoding current image to a compressed restored image, and generating a stored image by comparing the compressed restored image with the actual image, wherein the stored image is the compressed restored image for the actual image. If the distortion of the image is larger than a predetermined error range, the step B) determined according to a predetermined identification code; C) overdriving the current restored image to provide a corrected driving image; And D) selectively providing the corrected driving image as the transmission image, and if the stored image is determined to be in accordance with the identification code, providing the actual image as the transmission image.

For a better understanding of the present invention and its operational advantages, and the objects attained by the practice of the present invention, reference should be made to the accompanying drawings, which illustrate preferred embodiments of the invention, and the accompanying drawings. In understanding each of the figures, it should be noted that like parts are denoted by the same reference numerals whenever possible. Incidentally, detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

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

1 is a block diagram illustrating an image processing apparatus according to an embodiment of the present invention. Referring to FIG. 1, the image processing apparatus of the present invention receives a real image RLIMG and generates a transmission image TRIMG. The image processing apparatus of the present invention includes a compression restoring block 100, a distortion processing block 200, an overdrive block 300, and a transmission block 400.

The compression restoring block 100 encodes the real image RLIMG and compresses it into an encoding current image ENPRIMG. Then, the compression restoring block 100 restores the encoding current image ENPRIMG to a current restoring image PRREIMG. 300). In addition, the compression restoring block 100 provides the encoding compression image ENLNIMG to the distortion processing block 200 according to the encoding current image ENPRIMG.

The compression restoring block 100 includes a compression unit 110 and a current image restoration unit 130. The compression unit 110 encodes the real image RLIMG to provide the encoded current image ENPRIMG, and compresses and stores the encoded current image ENPRIMG as the encoded compressed image ENLNIMG. The current image restoration unit 130 decodes and restores the encoded current image ENPRIMG to provide the current restored image PRREIMG.

2 is a view illustrating the compression unit 110 of FIG. 1 in detail. Referring to FIG. 2, the compression unit 110 includes an encoding unit 111 and a compression memory 113.

The encoding unit 111 encodes the real image RLIMG to generate the encoded current image ENPRIMG. The compressed memory 113 compresses and stores the encoded current image ENPRIMG as the encoded compressed image ENLNIMG.

Referring back to FIG. 1, the distortion processing block 200 includes a distortion processing unit 210 and a frame memory 230, and preferably further includes a previous image restoration unit 250.

The distortion processing unit 210 receives the real image RLIMG and the encoded compressed image ENLNIMG to generate a confirmation image CFIMG. In this case, the confirmation image CFIMG is mainly determined as the encoded compressed image ENLNIMG. However, when the compressed restored image LNREIMG reconstructing the encoded compressed image ENLNIMG is distorted larger than an error range with respect to the real image RLIMG, the identification image CFIMG is determined as an identification code NTCOD. do.

In this case, the 'error range' may be embedded in the distortion processing unit 210 by the designer, or may be provided from the outside by the user. And, the identification code (NTCOD) can be embedded by the designer.

3 is a view illustrating the distortion processing unit 210 of FIG. 1 in detail. Referring to FIG. 3, the distortion processor 210 includes an image restoration unit 211, a compression error check unit 213, and a code selection unit 215.

The image restoration unit 211 restores the encoded compressed image to the compressed restored image LNREIMG and provides the compressed error checking unit 213.

The compression error check unit 213 generates the error check signal XDECH by comparing the compressed restored image LNREIMG with the real image RLIMG. At this time, the error check signal XDECH is activated when the compressed restored image LNREIMG is larger than the 'error range' with respect to the real image RLIMG.

The code selection unit 215 selectively provides the encoded compressed image ENLNIMG as the confirmation image CFIMG. When the compressed restored image LNREIMG is smaller than the 'error range' for the real image RLIMG, that is, when the error check signal XDECH is deactivated, the encoded compressed image ENLNIMG is selectively checked. It is provided as an image CFIMG. On the other hand, when the compressed restored image LNREIMG is larger than the 'error range' with respect to the real image RLIMG, that is, when the error check signal XDECH is activated, the identification code NTCOD is checked. It is provided as an image CFIMG.

Referring back to FIG. 1, the frame memory 230 stores the identification image CFIMG and provides the identification image CFIMG to the transmission block 400 and the previous image restoration unit 250 as the storage image STIMG.

The previous image restorer 250 decodes the stored image STIMG and provides the overdrive block 300 as a previous restored image BEREIMG.

4 is a view illustrating the previous image restoration unit 250 of FIG. 1 in detail. Referring to FIG. 4, the previous image restorer 250 includes a previous image memory 251 and a previous image decoding unit 253. The previous image memory 251 stores the stored image STIMG in line units. The previous image decoding unit 253 restores an image stored in the previous image memory 251 to generate a previous restored image BEREIMG.

Referring back to FIG. 1, the overdrive block 300 overdrives the current restored image and provides the corrected driving image to the transmission block 400. Here, overdriving refers to 'accelerating the response speed by applying a voltage higher than the normal voltage to the video data signal'.

In addition, the overdrive block 300 provides the actual image RLIMG as the corrected driving image DRIMG when the current restored image PREREIMG is read as a still image with respect to the previous restored image BEREIMG. . In this case, as described above, the previous restored image BEREIMG is determined according to the stored image STIMG.

FIG. 5 is a diagram illustrating in detail the overdrive block 300 of FIG. 1. Referring to FIG. 5, the overdrive block 300 includes a lookup table 310, a still image reading unit 330, and an interpolation unit 350.

The lookup table 310 stores predetermined 'correction data' as is well known to those skilled in the art.

The still image reading unit 330 compares the current restored image PREREIMG with the previous restored image BEREIMG to read whether the current restored image PRREIMG is a still image. Then, according to the comparison result, the still image reading unit 330 generates a current selection image (PRSEIMG).

In this case, when the current restored image PREREIMG is read as a still image, the current selected image PRSEIMG is generated according to the actual image RRLIM. On the other hand, if the current restored image PRREIMG is read as not being a still image, the current selected image PRSEIMG is generated according to the current restored image PRREIMG.

The interpolation unit 350 interpolates the current selection image PRSEIMG provided from the still image reading unit 330 using the lookup table 310 to provide the corrected driving image DRIMG.

Referring back to FIG. 1, the transmission block 400 selectively provides the corrected driving image DRIMG as the transmission image TRIMG. That is, if it is determined that the stored image does not correspond to the identification code, the transmission block 400 provides the corrected driving image DRIMG as the transmission image TRIMG. On the other hand, the transmission block 400 provides the real image RLIMG as the transmission image TRIMG when it is determined that the stored image corresponds to the identification code NTCOD.

The transmission block 400 includes a code checker 410 and a transmission selector 430. The code check unit 410 checks the stored image STIMG and generates a code check signal XCHE. At this time, the code check signal XCHE is activated when the stored image STIMG is determined to be in accordance with the identification code NTCOD.

The transmission selector 430 selectively provides the corrected driving image DRIMG as the transmission image TRIMG. That is, when the code check signal XCHE is deactivated, the transmission selecting unit 430 provides the corrected driving image DRIMG as the transmission image TRIMG. On the other hand, when the code check signal XCHE is activated, the transmission selector 430 provides the actual image RLIMG as the transmission image TRIMG.

The code selection unit 215 selectively provides the encoded compressed image ENLNIMG as the confirmation image CFIMG. When the compressed restored image LNREIMG is smaller than the 'error range' for the real image RLIMG, that is, when the error check signal XDECH is deactivated, the encoded compressed image ENLNIMG is selectively checked. It is provided as an image CFIMG. On the other hand, when the compressed restored image LNREIMG is larger than the 'error range' with respect to the real image RLIMG, that is, when the error check signal XDECH is activated, the identification code NTCOD is checked. It is provided as an image CFIMG.

In summary, in the image processing apparatus of the present invention as described above, when the compressed restored image LNREIMG in which the actual image RLIMG is compressed and then restored is smaller than the 'error range' with respect to the actual image RLIMG, The error check signal XDECH is activated. Accordingly, the real image RLIMG is directly transmitted to the transmission image TRIMG. As a result, distortion of the transmitted image is greatly reduced.

In the image processing apparatus of the present invention as described above, the over-drive block for over-driving the current restored image by compressing and reconstructing the actual image to provide a corrected driving image, and optionally providing the corrected driving image as the transmission image, When the compressed and reconstructed image has an error more than the error range than the actual image, a transmission block provided as the transmission image for transmitting the actual image is provided.

Therefore, according to the image processing apparatus and the image processing method of the present invention, the distortion phenomenon of the transmission image is minimized while the image is transmitted using the compressor method.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (12)

In the image processing apparatus for receiving a real image and generating a transmission image, A compression restoring block configured to restore the encoded current image to a current restored image after encoding the actual image and compressing the encoded current image into an encoded current image; A distortion processing block for restoring an encoded compressed image according to the encoding current image to a compressed restored image, and generating a stored image by comparing the compressed restored image with the actual image, wherein the stored image is the compressed restored image for the actual image. The distortion processing block determined according to a predetermined identification code when the distortion of the image is larger than a predetermined error range; An overdrive block for overdriving the current restored image to provide a corrected driving image; And A transmission block for selectively providing the corrected driving image as the transmission image, and when the stored image is determined to be in accordance with the identification code, the transmission block providing the actual image as the transmission image Image processing device. The method of claim 1, wherein the compression recovery block A compression unit which encodes the real image and provides the encoded current image and compresses and stores the encoded current image as the encoded compressed image; And And a current image restorer configured to decode and restore the encoded current image to provide the current restored image. The method of claim 2, wherein the compression unit An encoding unit for encoding the real video to generate the encoded current video; And a compression memory configured to store the encoded current image and provide the encoded compressed image as the encoded compressed image. The method of claim 1, wherein the distortion processing block A distortion processor for generating a confirmation image by receiving the real image and the encoded compressed image, wherein the confirmed image is determined to correspond to the encoded compressed image, and the compressed restored image reconstructs the encoded compressed image. The distortion processor determined according to the identification code when the distortion is larger than the error range; And And a frame memory for storing the identification image and providing the identification image as the stored image. The method of claim 4, wherein the distortion processing unit An image restoration unit for restoring the encoded compressed image to the compressed restored image; A compression error check unit which compares the compressed restored image with the actual image and generates an error check signal activated according to the compressed restored image that is larger than the error range with respect to the actual image; And And a code selection unit for selectively providing the encoded compressed image as the confirmation image, wherein the code selection unit provides the identification code as the confirmation image according to activation of the error check signal. Device. The method of claim 4, wherein the distortion processing block And a previous image restoration unit which decodes the stored image and provides a previous restored image. The method of claim 6, wherein the previous image restoration unit A previous image memory for storing the stored image; And And a previous image decoding unit for restoring the image stored in the previous image memory to generate the previous restored image. The method of claim 1, wherein the overdrive block And when the current restored image is read as a still image with respect to a previous restored image, providing the actual image as the corrected driving image, wherein the previous restored image is determined according to the stored image. The method of claim 8, wherein the of the drive block A lookup table for storing correction data; A still image reading unit for comparing the current restored image with the previous restored image to generate whether the current restored image is a still image and generating a current selected image according to the compared result; And And an interpolation unit for interpolating the current selected image provided from the still image reading unit using the lookup table and providing the corrected driving image. The method of claim 9, wherein the current selection image is When the current restored image is read as a still image, it is generated according to the actual image. And when the current restored image is read as being not a still image, the image processing apparatus generated according to the current restored image. The method of claim 1, wherein the transmission block A code check unit generating a code check signal activated in response to the stored image according to the identification code; And And a transmission selection unit for selectively providing the corrected driving image as the transmission image, wherein the transmission selection unit provides the actual image as the transmission image according to activation of the code check signal. . In the image processing method of the image processing apparatus for receiving a real image and generating a transmission image, A) step of restoring the encoded current image to a current restored image after encoding the actual image and compressing it into an encoded current image; B) restoring an encoded compressed image according to the encoding current image to a compressed restored image, and generating a stored image by comparing the compressed restored image with the actual image, wherein the stored image is the compressed restored image for the actual image. If the distortion of the image is larger than a predetermined error range, the step B) determined according to a predetermined identification code; C) overdriving the current restored image to provide a corrected driving image; And D) providing the corrected driving image as the transmission image, and if the stored image is determined to be in accordance with the identification code, providing the actual image as the transmission image. An image processing method of an image processing apparatus.

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