KR0185843B1 - A lossless decoder - Google Patents

Abstract

The present invention relates to a lossless decoder, comprising: an image data detector (320) for detecting and outputting subsampled image data from image data output through an entropy decoding unit (300); An error data detector 340 for detecting and outputting error data from the image data output through the entropy decoding unit 300 according to the input control signal; A first image restorer 360 which extends and restores the image data in a horizontal direction by using the image data input from the image data detector 320 and the error data input from the error data detector 340; A second image restorer 380 which extends and restores the image data in a vertical direction by using the image data input from the first image restorer 360 and the error data output from the error data detector 340; ; It is determined whether the image data outputted through the second image restorer 380 is equal to the size of the original image data, or the image data is input to the first image restorer 360 and the image data is restored. The control signal is input to the error data detector 340 to detect the error data used to detect the error data, and if the image data output through the second image restorer 380 is equal to the size of the original image data, the image data is inputted. It is configured to include a selection unit 400 for outputting, it is possible to restore the compressed image data to the original image data by a lossless encoder for compressing still image data in a binary tree structure.

Description

Lossless decoder

1 is a schematic diagram of a conventional lossless encoder.

2 is a diagram showing three samples used for spatial prediction in a conventional lossless encoder.

3 is a schematic configuration diagram of a lossless encoder corresponding to a lossless decoder according to the present invention.

4 is a diagram showing an image compressed in stages by the lossless encoder of FIG.

5 is a schematic diagram of a lossless decoder according to the present invention.

6 illustrates an image reconstructed in stages by a lossless decoder according to the present invention.

* Explanation of symbols for main parts of the drawings

300: entropy decoding unit 320: image data detection unit

340: error data detection unit 342: first error data detection unit

344: second error data detection unit 360: first image restoration unit

362: first even field prediction unit 364: first even field restoration unit

366: first synthesis unit 380: second image restoration unit

382: second even field prediction unit 384: second even field restoration unit

386: second synthesis unit 400: prediction unit

The present invention relates to a lossless decoder which restores compressed still image data to original image data so as not to lose image information. In particular, the present invention relates to a lossless decoder that restores still image data compressed in a binary tree structure to original image data. It is about.

In general, there are loss loss coding and lossless decoding methods for compressing still images, and loss loss coding allows loss of some information to the extent that it does not affect a person. High extrusion rates up to ˜60: 1 can be obtained.

Lossless encoding, on the other hand, is a method of encoding the image information so that the original information is not lost. The lossless coding is mainly used to compress medical information and image information which may have serious consequences if the original information is lost. Not so high as much.

As shown in FIG. 1, the lossless encoder includes a predictor for predicting a next pixel value from three adjacent pixels, and comparing the predicted pixel value with an actual pixel value. And an entropy encoder for outputting compressed image data by performing Huffman coding or arithmetic coding.

That is, as shown in FIG. 2, seven predictor configuration methods are specifically summarized in Table 1 to predict the pixel value X from the adjacent pixel values A, B or C.

The difference between the predicted pixel value X and the actual pixel value X thus obtained becomes lossless compression by entropy coding.

As the entropy coding method, Huffman or arithmetic coding can be selected.

In addition, the lossless operation mode input image prediction is free within 2 to 16 bits / sample, and any of the seven predictor configuration methods may be used.

However, such a conventional lossless predictive encoder has a problem that its value continues to accumulate when an error occurs.

To solve this problem, a lossless encoder that compresses still image data in a binary tree structure has already been proposed.

That is, as shown in FIG. 3, the even field forming unit 100 filters the predetermined even field among the frames implementing the still image to form the even field; An odd field forming unit 120 for forming the odd field by filtering a predetermined odd field among frames for implementing a still image; An even field predictor 140 implementing an even field predicted based on a comparison between pixel values in a horizontal direction of the even field formed by the even field forming unit 100; An error image forming unit 160 for forming an error image between the predicted even field provided from the even field predictor 140 and the odd field provided from the odd field forming unit 120; A first even field forming unit 180 forming an even field predicted based on a comparison between pixels in a vertical direction of the even field formed by the even field forming unit 100; A first even field predictor (200) for forming an even field predicted based on a comparison between the even fields formed by the first even field forming unit (180); A first odd field forming unit 220 forming an odd field predicted based on a comparison between pixels in an odd field formed by the odd field forming unit 120 in a vertical direction; A first error image forming unit 240 for forming an error image between the predicted even field provided from the first even field predictor 200 and the odd field provided from the first odd field forming unit 220; And a frame memory 260 for storing, restoring, and outputting an image output from the error image forming unit 160 and the first error image forming unit 220.

In the conventional lossless encoder configured as described above, first, a frame of a still image, that is, an image frame formed of an even field and an odd field, is formed by forming an even field number 100 and an odd field as shown in FIG. Each is provided as a part 12.

The even field forming unit 100 subsamples the input still image to convert even field lines (eg, even line 1, even line 2, even line 3, even line 4) in the image frame to the even field predictor 140. It will take the form of FIG. 4 (b).

Here, the even field prediction unit 140 provides even field lines (eg, even line 1, even line 2, even line 3, even line 4) in an image frame which is subsampled from the even field forming unit 100 and input. The operation is performed between the pixels of each even line in the horizontal direction.

For example, an operation value (A + B / 2, B + C / 2) between pixel values (eg, A, B, C, and G) existing on even lines 1 may be obtained.

In addition, the odd field forming unit 120 receives an odd field line (eg, odd line 1, odd line 2, odd line 3, odd line 4) in an image frame in which the still image is subsampled, and each wood line in the horizontal direction. The operation is performed between the pixels.

For example, operation values A1 + B1 / 2, B1 + C1 / 2 between pixel values (eg, A1, B1, C1, and G1) existing in odd line 1 are obtained.

Therefore, the error image forming unit 160 subtracts the prediction value between the even fields calculated and input from the even field prediction unit 140 and the prediction value of the odd field output from the odd field forming unit 120.

Here, the result obtained is implemented as an error image, which takes the form of FIG. 4 (C).

The error image formed by the error image forming unit 160 is stored in the frame memory 260 and the error image is stored.

Next, the first even field forming unit 180 forms a still field input from the even field forming unit 100 in the vertical direction between even fields and provides the even field to the first even field predicting unit 200. At this time, it takes the form as shown in FIG.

The first even field predictor 200 receives an even field (eg, even line 1, even line 2, even line 3, even line 4) in an image frame provided from the first even field forming unit 180. The operation is performed in the vertical direction between even lines.

That is, a sum of pixel values of even lines 1 and pixel values of even lines 2 and dividing by two; A pixel value of the even line 2 and a pixel value of the even line 3 are summed and divided by two; Data obtained by adding the pixel value of the even line 3 and the pixel value of the even line 4 and then summing all values divided by 2 are provided to the first error image shape unit 210.

The first odd field forming unit 220 implements the odd field formed by the odd field forming unit 120 based on the comparison between the odd fields in the vertical direction to the first error image forming unit 240. Will be provided.

The first error image forming unit 240 forms an error image between the predicted even field provided from the first even field predictor 200 and the odd field provided from the first odd field forming unit 220 to form a frame memory ( 260).

Therefore, in the frame memory 260, an image input from the error image forming unit 160 and an image received and stored from the first error image forming unit 240 are provided to a buffer and an entropy coding unit. Will be done.

Only the image of (a) shown in FIG. 4 and (c) (e) (g) (i) shown in FIG. 4 exists. In this case, the image of FIG. Instead, the original video is a sampled image, and the other video shown in FIG. 4 (C), E, G, and C is an error image.

Therefore, the image obtained by sampling the original image rather than the error image is coded using the entropy coding unit 280.

However, in the related art, only a lossless encoder that compresses still image data in a binary tree structure has been proposed, but there is a problem in that a lossless decoder corresponding to the lossless encoder cannot be implemented.

Accordingly, an object of the present invention is to provide a lossless decoder for reconstructing image data compressed by a lossless encoder that compresses still image data in a binary tree structure to original image data. There is this.

Lossless decoding according to the present invention for achieving the above object comprises: an entropy decoding unit for entropy decoding and output the compressed and transmitted image data; An image data detector for detecting and outputting sub-sampled image data from the image data output through the entropy decoding unit; An error data detector for detecting and outputting an error data from the image data output through the entropy decoding unit according to an input control signal; A first image restorer configured to expand and restore horizontally the image data input from the image data detector by using the image data input from the image data detector and the error data input from the error data detector; A second image restorer which extends and restores the image data input from the first image restorer in a vertical direction by using the image data input from the first image restorer and the error data output from the error data detector; ; Determine whether the image data outputted through the second image restorer is equal to the size of the original image data, or input the image data to the first image restorer and detect error data used to restore the image data. And a selector for inputting a control signal to the error data detector and outputting the image data when the image data output through the second image restorer is equal to the size of the original image data.

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

5 is a schematic configuration diagram of a lossless decoder according to the present invention. The lossless decoder according to the present invention includes an entropy decoding unit 300 for entropy decoding and outputting compressed and transmitted image data; An image data detector 320 for detecting and outputting subsample Riodine image data from the image data output through the entropy decoding unit 300; An error data detector 340 for detecting and outputting error data from the image data output through the entropy decoding unit 300 according to the input control signal; A first image restorer 360 configured to expand and restore horizontally the image data input from the image data detector 320 by using the error data input from the image data detector 320 and output the horizontal data; The image data input from the first image restorer 340 is extended and reconstructed vertically using the image data input from the first image restorer 340 and the error data output from the error data detector 340. A second image restoring unit 380 for outputting; It is determined whether the image data output through the second image restorer 380 is the same as the size of the original image data, or the image data output through the second image restorer 380 is converted into the first image restorer ( The control signal is input to the error data detector 340 to detect error data used to restore the image data inputted to the first image restorer 360 and the second image restorer 360. If the image data output through the unit 360 is equal to the size of the original image data, it comprises a selection unit 400 for outputting the image data.

The error data detector 340 may include a first error data detector 342 for detecting and outputting error data used in the first image restorer 360 according to a control signal output from the selector 400; The second error data detector 344 detects and outputs error data used in the second image restorer 380 according to the control signal output from the selector 400.

The video restoring unit 360 uses the video data inputted through the video data detecting unit 320 and the selecting unit 400 as an odd field and evenly transversely from each adjacent pixel value of the video data. A first even field predictor 362 for predicting and outputting a field; A first even field restoring unit for restoring an actual even field using each pixel value of the even field output from the first even field prediction unit 362 and the error data output from the first error data detection unit 342 ( 364) and; The first combiner 366 combines an odd field input to the first even field predictor 362 and an even field restored and output from the first even field restorer 364.

The second image restorer 380 uses the image data inputted through the first image restorer 360 as an odd field to predict an even field vertically from the image data and each adjacent pixel value. The pixel values of the even field output from the second even field predictor 382 and the second even field predictor 382 and the error data output from the second error data detector 344 are actually used. A second even field restorer 384 for restoring even fields; An odd field input to the second even field predictor 382 and a second synthesizer 386 for synthesizing and outputting the even field restored and output from the second even field restorer 384.

Referring to the operation and effect of the lossless decoding according to the present invention configured as described above are as follows.

The image data detector 320 detects and outputs subsampled image data from the image data entropy decoded and output by the entropy decoding unit 300.

Then, the first error data detector 342 of the error data detector 340 is connected to the first even field restorer 364 of the first image restorer 360 according to the control signal output from the selector 400. The error data used is detected and output, and the second error data detector 344 transmits the error data to the second even field restorer 384 of the second image restorer 380 according to the control signal output from the selector 400. Detects and outputs the error data used.

The first even field predictor 362 of the first image restorer 360 uses the image data inputted through the image data detector 320 or the selector 400 as an odd field to display the image data. The even field is predicted and output in the horizontal direction from each adjacent pixel value, and the first even field restorer 364 outputs the first error value and the first error value of each pixel of the even field output from the side part 362 to the first even field. The actual even field is restored using the error data output from the data detector 342, and the first synthesizer 366 restores the odd field and the first even field inputted to the first even field predictor 362. FIG. The even field reconstructed and output from the block 364 is synthesized and output.

That is, the image data input from the image data detector 320 is transversely formed by using the image data input from the image data detector 320 and the error data input from the error data detector 340. This is to restore the output.

As described above, the second even field predictor 382 of the second image restorer 380 uses the image data inputted through the first image restorer 360 as an odd field, and each adjacent pixel of the image data. The even field is predicted and output from the value in the vertical direction, and the second even field restoring unit 384 outputs each pixel value of the even field output from the second even field prediction unit 382 and the second error data detector ( The actual even field is restored using the error data outputted at 344, and the second synthesis unit 386 performs the odd field input to the second even field predictor 382 and the second even field restorer 384. The even field restored and outputted from) is synthesized and output.

That is, the image data input from the first image restorer 340 is extended in the vertical direction by using the image data input from the first image restorer 340 and the error data output from the error data detector 340. Is to restore the output.

Meanwhile, the selector 400 determines whether the image data output through the second image restorer 380 is the same as the size of the original image data or the image output through the second image restorer 380. A control signal is input to the error data detector 340 to detect data used for inputting data to the first image restorer 360 and restoring image data input to the first image restorer 360. On the other hand, if the image data output through the second image restorer 360 is equal to the size of the original image data, the image data is output.

That is, the number of times of restoring the image data through the first image restoring unit 360 and the second image restoring unit 380 is changed depending on the number of times of subsampling in the lossless incubator corresponding to the present invention. will be.

FIG. 6 is a diagram showing projections gradually restored by the lossless decoder according to the present invention. The present invention will be described again with reference to FIG.

The image data detecting unit 320 sub-samples the image data A, B, C, D, E, F, G, H, ... from the image data output through the entropy decoding unit 300. ), And the first error data detection unit 342 detects the error data (a, b, c, d, e, f, g, h, ...) as shown in FIG. Detect and output.

Then, the first even field prediction unit 362 uses the following first equation from the image data A, B, C, D, E, F, G, H, ... to make an even number as shown in FIG. Field data (a ', b', c ', d', e ', f', g ', h', ...) are predicted and output.

Predicted pixel value a '= (A + B) / 2. First Formula

In addition, the first even field restorer 364 performs pixel values a ', b', c ', d', e ', f', of the even field output from the first even field predictor 362. g ;, h ', ...) and the error data (a, b, c, d, e, f, g, h, ...) output from the first error data detector 342 using the following equation The actual even fields (a, b, c, d, e, f, g, h, ...) as shown in FIG.

Pixel value (a) of actual even field = error data (a) + predictive pixel value (a ')

Then, the first synthesis unit 366 restores the odd fields A, B, C, D, E, F, G, H ... and the first even field inputted to the first even field prediction unit 362. The even field (a, b, c, d, e, f, g, h, ...) restored by the section 364 is synthesized to restore image data as shown in FIG.

That is, the image data of FIG. 6 (bar) is extended and reconstructed in the horizontal direction in the same manner as described above to generate the image data as shown in FIG. By using the image data input from the unit 340 and the error data output from the error data detector 340, the image data input from the first image restorer 340 may be extended and restored in the vertical direction. The video data is restored as shown in FIG.

By repeating this process, it is possible to create and output the original image data finally restored as shown in FIG.

As described above, according to the present invention, image data compressed by a lossless encoder that compresses still image data in a binary tree structure may be restored to original image data.

Claims (4)

A lossless decoder which restores compressed still image data to original image data so as not to lose image information, comprising: an entropy decoding unit 300 for entropy decoding and outputting the compressed and transmitted image data; An image data detector 320 for detecting and outputting sub-sampled image data from the image data output through the entropy decoding unit 300; An error data detector 340 for detecting and outputting error data from the image data output through the entropy decoding unit 300 according to the input control signal; The image data input from the image data detector 320 and the error data input from the error data detector 340 are used to extend and restore the image data input from the image data detector 320 in a horizontal direction. 1 image restoration unit 360; The image data input from the first image restorer 360 is extended and restored using the image data input from the first image restorer 36 and the error data output from the error data detector 340. A second image restoring unit 380 for outputting; It is determined whether the image data outputted through the second image restorer 380 is equal to the size of the original image data, or the image data is input to the first image restorer 360 and the image data is restored. If a control signal is input to the error data detector 340 to detect commonly used error data, and the image data output through the second image restorer 380 is equal to the size of the original image data, the image data. Lossless decoder characterized in that it comprises a selection unit for outputting a (400). The first error data of claim 1, wherein the error data detector 340 detects and outputs error data used in the first image restorer 360 according to a control signal output from the selector 400. And a second error data detector 344 for detecting and outputting error data used in the second image restorer 380 according to a control signal output from the selector 400. Lossless decoder, characterized in that. 2. The method according to claim 1, wherein the first image restorer (360) uses the image data input through the image data detector (320) and the selector (400) as odd fields, and each adjacent pixel value of the image data. A first even field predictor 363 for predicting and outputting an even field in a horizontal direction from the first field; A first even field restoring unit for restoring an actual even field using each pixel value of the even field output from the first even field prediction unit 362 and the error data output from the first error data detection unit 342 ( 364) and; And a first synthesizer 366 for synthesizing and outputting the even field inputted to the first even field predictor 362 and the even field restored and output from the first even field restorer 364. Lossless decoder characterized by. The image reproducing unit 380 of claim 1, wherein the second image reconstructor 380 uses the image data input through the first image reconstructor 360 as an odd field and is even in the vertical direction from each adjacent pixel value of the image data. Pixel values of the even field output from the second even field predictor 382 and the second even field predictor 382 that predict and output a field, and the error data output from the second error data detector 344. A second even field restorer 384 for restoring the actual even field using; And a second synthesizer 386 for synthesizing and outputting the even field inputted to the second even field predictor 382 and the even field restored and output from the second even field restorer 384. Lossless decoder characterized by.