DE3917085C2 - Circuit arrangement for filtering a video signal - Google Patents

Description

The invention relates to a circuit arrangement for fil a video signal in which the data of the image points of a video image combined into blocks and are coded in blocks and in the so-called for each block called secondary information belong with a tax unit from the secondary information for the pixels of a block calculates a figure of merit with a digital one Filter, the data of the pixels and those related to them Pixels belonging to pixels are supplied, whereby the digital filter contains means with which from the Gü number of pixels determines the filter coefficients be used to calculate the filtered data this Pixel are required.

Such a circuit arrangement can, for example, in a VCR can be used to get that from the video recorded incoming signal before its optical reproduction filter on a monitor. The purpose of such a filter is the improvement of the picture quality.

This offers another application in the System described in DE 37 26 520 for the transmission of Vi deo pictures. Again, the above arrangement can on the receiving side before optical playback be used on a monitor.

In the known system, a so-called hybrid co used, the task of which is that of a Video data source coming video data with ge if possible minimal loss of information in a signal with as much as possible  recode low bit rate.

The video data coming from the video data source will be passed to the encoder in so-called blocks. On such video data block contains the data of certain Pixels of a video image, which are elements of a qua dramatic number matrix. So z. B. a video data block from the chrominance values of the first 8 pixels of the first 8 lines of a video picture best hen. Each video image is broken down into data blocks of the same size sets.

With the known hybrid encoder z. B. 8x8 Vi deodata blocks of the just come from the video data source the video image (hereinafter the current video image or spoken of the current data block) first compare with blocks from the previous picture chen, which are stored in an image memory and the determines the block that is most similar to the current block most beautiful. A result block is then formed, the either consists of the difference between the two blocks or is the unchanged current data block.

Under the block of the previous video picture, the egg corresponds to a block of the current video image, is in the the block of the previous video image follows understood, which is in the same place as the ak current block of the current video image. Usually is the corresponding block understood in this sense the block that is most similar to the current block. However, the case may arise in which the each other most similar blocks different positions in the two consecutive video images. This case often occurs in video images in which people or move objects against a solid background.  

The position of the two blocks is determined by a Motion vector specified. Is this vector the Zero vector, the most similar blocks are again each other speaking blocks in the sense given above.

The result block mentioned above (the difference block or the original block) becomes one Subjected to Fourier transformation (cf. also DE 36 13 393) and then quantized. Is after quantization, no element of the result block it does not become significantly different from zero at all transfer. Is at least the value of an element of the Result block (in the following, for the sake of simplicity, like which is just called a block) above a threshold becomes one Huffman coding made and the values of the block written as main information in a buffer memory ben.

Also in coded form are in the buffer memory including the following so-called secondary information (side information) registered:

• 1. The transformed and quantized block is the original jumping block.
• 2. The transformed and quantized block is a dif reference block and its motion vector has the amount Zero.
• 3. The transformed and quantized block is a dif reference block and its motion vector has one of Zero different amount.
• 4. The transformed and quantized block only exists from zeros and its motion vector has one from zero different amount.  
• 5. The transformed and quantized block only exists from zeros and its motion vector has the amount Zero.
• 6. The number of the quantization curve with which the Block has been quantized.

Main and secondary information of the blocks are then with constant bit rate of z. B. 384 kbit / s from Buffer memory read out and transferred to a receiver gene, in such a way that the receiver with its hybrid De encoder is able to handle the accumulating for a block Information again in main and secondary information disassemble and undo the individual coding steps close.

The structuring of the transmitted video images into blocks has the disadvantage that when playing the pictures on a receiver-side screen interference (artifacts) occur that are a result of this structuring. These disorders include the fact that on the reproduced video image block boundaries more or less are clearly recognizable. Therefore, to improve the Image quality a post processing of the transmitted video signal required.

For post-processing, EP 0 270 405 A1 describes a Ver drive and described an arrangement with which the Rau in the block-wise coding / decoding of Vi deo images should be reduced, also before the optical reproduction of the video images on the Emp start side.

As additional information, which is used to calculate the filtered Data of a pixel is used in the  EP 0 270 405 A1 the current state of the encoder - esp in particular the fill level of the buffer tank - specified. No other side information is mentioned. Correspond According to EP 0 270 405, a quality figure is given for each block (called parameter NR there) with which the Koef efficiency of the filter can be determined. The disadvantage of known method is that blocks that are opposite the previous corresponding block of a video image are unchanged - for those mentioned under point 5 te additional information applies - who is inadequately filtered the, d. H. cannot be filtered according to their quality.

The invention has for its object a scarf arrangement for filtering a video signal with the to specify the characteristics mentioned at the outset, which filter Execution process so that it the quality of the fil terenden blocks is adapted.

This task is carried out in a circuit arrangement with the solved at the outset in that the Quality figures are stored in a quality memory, in a storage space for egg per block of a video image ne quality figure is provided, and the control unit for the current block calculated figure of merit in the figure of merit only registers if the current ne beninformation shows that the data of the current Blocks compared to the data of the corresponding block of the have changed previous video image.

Advantageous refinements are in the subclaims remove.

Using an exemplary embodiment and the figure, the Invention will be explained in more detail.  

The figure shows the basic circuit diagram of a Videoemp catcher with an arrangement according to the invention.

In the figure, building blocks 1 and 4 represent a decoder as it is, for. B. is described in DE 36 13 343. The block 4 is the image memory of the decoder and the block 1 contains the remaining Decodierein devices that are required for decoding the transmitted video signal, including a functional unit that performs the separation of secondary information and main information in the transmitted video signal.

The main information of a block that has just been transmitted is used to supplement the blocks stored in the image memory 4 or their data so that a block of the last transmitted video picture results in PCM coding, while the secondary information of the block that has just been transmitted is passed to a control unit 2 fed and stored there first.

The control unit 2 calculates a so-called figure of merit for this block, the determination of which will be discussed in more detail below. This figure of merit is written into a figure of merit 3 under the conditions mentioned below. Each block of the memory 4 corresponds to a figure of merit written into the memory 3 ; this Ent is indicated in the figure by the structure of the memory 3 and 4 . The registration of the new figure of merit and thus the overwriting of the previously valid figure of merit takes place only if it emerges from the just received, ie current secondary information, that the current block differs from the corresponding block of the preceding video picture. This is always the case if the current secondary information is not the secondary information mentioned under point 5.

In order to display the image stored in the image memory 4 on a monitor 7 , the data of individual image points are read line by line from the image memory 4 and passed to a digital filter 5 for filtering. The filter 5 contains a memory for 3 video lines, from which filtered data are obtained.

A filtered line is passed on to an up converter 6 . The up converter 6 carries out an oversampling with the transmitted line, so that the number of pixels per line corresponds to the standard to which the monitor 7 is adapted.

With the transfer of the data of individual pixels from the image memory 4 into the filter 5 , the figure of merit assigned to a pixel to be filtered is simultaneously transferred from the memory 3 into the filter 5 . The figure of merit assigned to a pixel is the figure of merit of the block to which the pixel belongs.

The process of filtering can be done in the simplest Represent the form using the following equation:

where x _{k symbolize} the unfiltered data of the k-th pixel and y _i the filtered data of the i-th pixel. The c values are the filter coefficients. Only the neighboring pixels are used to determine the filtered data of the i-th pixel, so that the sum in (1) only passes through the pixels adjacent to the point i. In general, these pixels lie in one plane. This is why two-dimensional filtering is used. If they lie on a straight line - see below - one speaks of one-dimensional filtering.

The filter coefficients are determined by means provided in the filter 5 , inter alia from the figure of merit assigned to the i-th pixel. Quality figure 1 means the highest quality. If the pixel i the figure of merit 1 to ordered, then c₀ to 1 and all other Koeffizien be th made 0, ie, it is not effectively filtered because the filtered value y _i with the un-filtered value x _i matches. The deviation from this extreme case becomes increasingly greater the greater the figure of merit assigned to a pixel to be filtered. The precise ge dependency of the filter coefficients on the quality figures must be determined by a person skilled in the art.

In the present example, the filter coefficients are additionally made dependent on the data x _k of the pixels adjacent to the i-th pixel, specifically on the variance of this data. This means that the filtering is not linear or signal-adaptive. If the variance is small, a strong filtering is carried out, ie, in equation 1, the points adjacent to point i are provided with large c values. The person skilled in the art must determine details of the dependence of the coefficients on the variance and the figure of merit according to optimization principles.

Instead of the variance, the sum S _{i of} the difference amounts has also proven to be favorable, namely the difference between the data of the pixel i to be filtered and the data of the remaining pixels involved in the filtering. In other words:

where k runs through the same values as in Glei chung (1).

The approach of two-dimensional filtering according to Glei chung (1) is in the present example in two the following one-dimensional filtering of different Disassembled direction, d. that is, any one-dimensional filtering contains other neighbors of pixel i. In the first Filtering only takes into account the horizontal neighbors and with the second filtering the vertical Neighbours. The variance and the filter coefficients c are recalculated in the second filtering. At the second filtering will be the same as for the first filtering obtained y values in place of the original x values set (recursive).

In the present example, the quality figures are calculated according to the following explanations. Of the secondary information listed at the beginning, only one of the first five is transmitted with a block or instead of a block (this is the secondary information mentioned under points 4 and 5). The secondary information mentioned under point 6, i.e. the number of the quantization characteristic, is only transmitted if one of the circumstances stated under point 1, 2 or 3 applies to a block. In such a case, the number of the quantization characteristic is used as the figure of merit, because a characteristic with a larger number corresponds to a coarser quantization than a characteristic with a smaller number. The number of a characteristic curve is therefore a measure of the quality or image quality of a block. The quantization curve with the number 1 corresponds to the finest quantization and thus the figure of merit with the highest quality. The quality numbers stored in the quality number memory 3 are overwritten by the number of the quantization characteristic as soon as a block arrives for which one of the secondary information items 1 to 3 applies. If the secondary information is provided for a block under point 5, the old figure of merit is retained. In the event that the secondary information mentioned under point 4 applies, the old figure of merit is replaced by the figure of merit that was last written into the figure of merit memory and there has led to a change in the memory content.

Claims (4)

1. Circuit arrangement for filtering a video signal, in which the data of the pixels of a video image are combined into blocks and coded block by block, and in which so-called secondary information is heard for each block, with a control unit ( 2 ) which, from the secondary information of a block Figure of merit calculated with a digital filter ( 5 ) to which the data of the pixels and the associated figure of merit are supplied, the digital filter ( 5 ) containing means with which the filter coefficient is determined from the figure of merit of a pixel, which are used for the calculation the filtered data of this pixel are required, characterized in that
that the quality numbers are stored in a quality number memory ( 3 ), in which a memory space is provided for a quality number per block of a video image, and
the control unit ( 2 ) only writes the figure of merit calculated for the current block into the figure of merit memory if it follows from the current secondary information that the data of the current block have changed compared to the data of the corresponding block of the previous video image. 2. Circuit arrangement according to claim 1, characterized in that the digital filter ( 5 ) contains means with which the filter coefficients for filtering the data of a pixel are also determined depending on the differences in the data of all pixels involved in the filtering. 3. Circuit arrangement according to claim 2, characterized, that as a measure of the difference the sum of the difference amounts between the data of the pixel to be filtered the data of the others involved in the filtering Pixels is used. 4. Circuit arrangement according to claim 1, 2 or 3, characterized, that the two-dimensional filtering in several on top of each other the following one-dimensional filtering of different Direction is disassembled, with the successive one dimensional filtering can be performed recursively.