KR20000000982A - Adaptive and gradual transmitting system - Google Patents

Abstract

PURPOSE: An adaptive and gradual transmitting system is provided to improve display quality of an image CONSTITUTION: The system comprises a band division filter(200), a controller(400) and a selector(300). The band division filter(200) filters an input image signal by an orthogonal band division, and outputs negative band signals. The controller(400) generates an energy level sequence according to pixel mean level of the negative band signals and secondary moment, and outputs a selection control signal to select a negative band signal according to the energy level sequence. The selector(300) selects and outputs a negative band image signal from the output signals of the orthogonal band division filter(200) according to the selection control signal from the controller(400).

Description

ADAPTIVE PROGRESSIVE TRANSMISSION SYSTEM

The present invention relates to an adaptive gradual transmission system that allows a receiver to select a resolution. Particularly, in a rectangular band division scheme, a subband is selectively selected by using an average value and a second moment of pixels in a block. The present invention relates to an adaptive progressive transmission system for improving the quality of reconstructed images.

The conventional subband gradual transmission system uses a rectangular band division scheme, and as shown in FIG. 1, a one-dimensional rectangular low pass filter 101 which receives an image signal X (z1, z2) as an input. A compressor 102 for down sampling the output of the one-dimensional rectangular low pass filter 101, a one-dimensional rectangular low pass filter 111 for inputting the output of the compressor 102, and the one-dimensional rectangular low pass filter Compressor 112 for outputting the signal of the low frequency band by inputting the output of the filter 111, the one-dimensional rectangular high-pass filter 121, the output of the compressor 102, the one-dimensional rectangular high-pass A compressor 122 for downsampling the output of the pass filter 121, a one-dimensional rectangular high-pass filter 131 that takes an image signal x (z1, z2) as an input, and the one-dimensional rectangular high-pass filter ( A compressor 132 for downsampling the output of 101, the compressor 1 A one-dimensional rectangular low pass filter 141 having an output of 32), a compressor 142 for outputting a low frequency signal using the output of the one-dimensional rectangular low pass filter 141, and the compressor And a compressor (152) for downsampling the output of the one-dimensional rectangular high pass filter (151).

The conventional subband gradual transmission system configured as described above transmits only the signals of the low frequency band after filtering the input image signal X (z1, z2) by using a rectangular band division scheme.

In this case, only 25% of resolution is required to transmit only the low frequency band. On the other hand, when the receiver requires more resolution, that is, when the resolution of 50% or 75% is required, the low frequency and high frequency bands must be transmitted together.

That is, when the resolution of 50% is required, the outputs of the compressors 112 and 122 should be transmitted. When the resolution of 75% is required, the outputs of the compressors 112, 122 and 142 should be transmitted.

In other words, if a resolution of 75% is required, the outputs of the compressors 112, 122, and 142, which are minus the high frequency subbands in the vertical and horizontal directions, must be transmitted.

However, for some images, energy may be high in the high frequency subbands in the vertical and horizontal directions. That is, the energy of the output of the compressor 152 may be greater than the energy of the output of the compressor 142 depending on the pixel value in the screen.

As such, when a signal having a low energy subband is transmitted, image quality is degraded when the image is restored.

The present invention to solve the above problem is to adopt an adaptive gradual transmission system for improving the quality of the reconstructed image for the same data rate by selecting the subbands using the average value and the second moment of the pixels in the block in the rectangular band division scheme. The purpose is to provide.

In order to achieve the above object, according to the present invention, a rectangular band split filter means for outputting a subband video signal by filtering an input video signal by a rectangular band split scheme, and according to the resolution selection signal input from the outside, Each subband video signal output from the band-splitting filter means is input to output a selection control signal to select a subband signal by determining the energy rank of each subband using the average value and the second moment of the pixels in each subband. And control means, and selection means for selecting and outputting a subband video signal output from the rectangular band split filter means.

1 is a block diagram of an adaptive gradual transmission system according to the present invention.

Explanation of symbols on the main parts of the drawings

200: rectangular band division filter unit 210, 220, 250: low pass filter unit

211, 221, 251: low pass filter

212, 222, 232, 242, 252, 262: compressor 230, 240, 260: high pass filter

231, 241, 261: high pass filter 400: control unit

300: selection unit

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

As shown in FIG. 2, the adaptive gradual transmission system according to the present invention includes a quadrature band division filter unit 200, a controller 400, and a selector 300.

The rectangular band split filter 200 filters the input video signals X (z1 and z2) by using a rectangular band split scheme to output subband video signals, respectively. The input video signals X (z1 and z2) are output. Low pass filter 210 for low pass filtering and sampling in one dimension, and low frequency subband signal in the vertical and horizontal directions by filtering and sampling the output of the low pass filter 210 in one dimension. The low pass filter 220 outputting the I1) to the selector 300 and the output of the low pass filter 210 are subjected to one-dimensional high pass filtering and sampling to generate high frequency and low frequency subbands in the vertical and horizontal directions. High pass filter 230 for outputting signal I2 to the selection means 300, and high pass filter 240 for high pass filtering and sampling the input image signal X (z1, z2) in one dimension. The output of the high pass filter unit 240 is a one-dimensional low pass And the low pass filter 250 for outputting the high frequency and low frequency subband signal I3 in the vertical and horizontal directions to the selecting means 300, and the output of the high pass filter 240. And a high pass filter unit 260 for filtering and sampling one-dimensional high pass filter to output the high frequency subband signal I4 in the vertical and horizontal directions to the selector 300.

Here, the low pass filter unit 210, 220, 250 includes a low pass filter 211, 221, 251 for low pass filtering the input signal, and a compressor 212, 222, 252 for sampling and compressing the input signal. The high pass filter unit 230, 240, 260 includes a high pass filter 231, 241, and 261 for high pass filtering the input signal and a compressor 232, 242, and 262 for sampling and compressing the input signal. do.

The control unit 400 inputs each subband image signal output from the rectangular band split filter unit 200 according to a resolution selection signal input from the outside, and an average value and a second moment of pixels in each subband. By using (D (k)), the energy control of each subband is determined to output a selection control signal to select a subband signal.

Here, the energy rank is based on a comparison of primary energy magnitudes with an average value of pixels of a divided block of each subband calculated as an input of a subband image signal output from the rectangular band split filter 200. The second moment D (k) calculated as an input of the subband image signal of each divided block of the subband is determined in order of the energy magnitude of each subband based on a comparison of the secondary energy magnitudes.

In other words, the energy rank is primarily an energy level according to the average value of the pixels of each divided block of each subband calculated as an input of each subband image signal output from the rectangular band split filter unit 200. The number of blocks that are compared and determined and the second moment D (k) of each block of the corresponding subband calculated when the average value of the pixels of each divided block of the subband is equal to or greater than the set moment threshold, or Secondarily determined by the average value of the pixels in the block.

The selector 300 selects and outputs a subband image signal output from the rectangular band split filter 200.

The operation of the adaptive gradual transmission system according to the present invention configured as described above will be described.

First, the input image signal X (z1, z2) is input to the rectangular band-division filter unit 200, filtered by the rectangular band-division method, and output as subband image signals, respectively.

For example, a case of transmitting four subband signals will be described.

The input image signal X (z1, z2) is input to the low pass filter 210, low pass filtered and sampled in one dimension, and then inputs to the low pass filter 220 and the high pass filter 230 again. Low and high pass filtering and sampling are then output as low frequency subband signals (I1, I2).

That is, the input image signal X (z1, z2) is output as the low frequency subband signal I1 in the vertical and horizontal directions through the low pass filter 210 and the low pass filter 220. The output low frequency subband signal I1 is concentrated at 90% of the energy of the entire subband signal.

In addition, the input image signal X (z1, z2) is output as a high frequency and low frequency subband signal I2 in the vertical and horizontal directions through the low pass filter 210 and the high pass filter 230. .

In addition, the input image signal X (z1, z2) is input to the high pass filter unit 240, low pass filtering and sampling in one dimension, and then the low pass filter 250 and the high pass filter 260 again. It is inputted to the low pass or high pass filtered and sampled and then output as a high frequency subband signals (I3, I4).

That is, the input image signal X (z1, z2) is output as a low frequency and high frequency subband signal I3 in the vertical and horizontal directions through the high pass filter 240 and the low pass filter 250. .

In addition, the input image signal X (z1, z2) is output as a high frequency subband signal I2 in the vertical and horizontal directions through the high pass filter 240 and the high pass filter 260.

The four subband signals I1, I2, I3, and I4 output as described above are input to the selector 300 to select and output the corresponding subband signals under the control of the controller 400.

Thus, the operation of generating the selection control signal for controlling the selection unit 300 in the controller 400 will be described in detail.

The controller 400 first inputs each subband image signal output from the rectangular band-splitting filter unit 200 and uses the average value of the pixels in each subband and the second moment D (k). Determine the energy ranking of the subband.

That is, the average value of the pixels of the divided blocks of each subband, which are first calculated as an input of a subband image signal output from the rectangular band split filter unit 200, is used as a comparison criterion for energy magnitude. Energy ranks are determined in the order of the energy magnitudes based on the comparison of the secondary energy magnitudes D (k), which is calculated as an input of the subband image signal of each divided block of the subbands.

In other words, the energy rank is primarily compared to the energy magnitude according to an average value of pixels of each divided block of each subband, which is calculated as an input of each subband image signal output from the rectangular band split filter 200. Is determined, and if the average value of the pixels of each divided block of the subband is equal to or less than the set average threshold, the number of blocks whose secondary moment (D (k)) of each block of the corresponding subband calculated is greater than or equal to the set moment threshold, or The energy rank is secondarily determined by the average value of the pixels in the block.

The process of determining the energy rank in detail is as follows.

The original image (X (z1, z2)) of size M x M is converted into subband images (S1 (z1, z2), S2 (z1, z2), S3 (z1, z2), S4 (z1, z2) Let the partition, and dividing each of the sub-band image into blocks of size mxm (m / m) ² vectors. The average value of these vectors is calculated for each subband to determine the energy rank.

At this time, the low-frequency sub-band image signal (I1) output from the low pass filter unit 220 will be the first energy ranking at this time because the energy is concentrated more than 90%. On the other hand, most of the vectors of the subband image signal except the low frequency subband image signal I1 have an average value close to '0' in the subband image. That is, the second moment D (k) may be used as a comparison criterion for the energy of the subband smaller than the set average threshold value. Therefore, the average threshold is set to a value close to '0'.

Meanwhile, the second moment D (k) may be calculated as shown in Equation 1 below.

Where k is a subband vector and i is a pixel of the subband vector.

Since each subband image has an average and a variance close to '0', the second moment distribution of the vectors of each band is also combined with the entire band, and most of the vectors have values smaller than the moment threshold set for most vectors. For example, when the gray level is 256 and the set threshold is 2.5, the second moments of the vectors of most blocks are smaller than 2.5.

Secondarily, the second moment of each block of the subband image calculated to determine the energy rank is counted the number of blocks having a moment threshold of 2.5 or more, or the average value of the pixels of the block having a second moment of 2.5 or more is calculated. That is, the energy rank of the subbands is determined in order of the number of blocks having the second moment of each block of 2.5 or more, or the energy rank of the subbands is determined according to the average value of the pixels of the blocks having the second moment of each block of 2.5 or more. Decide

As described above, vectors having a second moment of 2.5 or less can be regarded as a flat region without relatively change in brightness value in the subband image. These vectors contain small energy and do not significantly affect the image quality of the reproduced image. Therefore, even if the portion smaller than 2.5, which is the moment threshold value, does not significantly affect the image quality of the reproduced video.

As a result, the second moment of the average value of the pixels and the second moments of the vectors of the subband images are calculated as a criterion of the energy ranking of the subband images, and the subband images having a higher value than the moment threshold are transmitted.

When the energy rank is determined according to the average value of the pixel and the second moment, a corresponding subband signal may be selected from four subband signals I1, I2, I3, and I4 according to a resolution selection signal input from the outside. It outputs a selection control signal so that it can

That is, if the receiver requires 25% of resolution, one subband signal may be selected from four subband signals. The low frequency subband signal I1 in the vertical and horizontal directions having the highest energy rank may be selected. 400, it will output the selection control signal.

In addition, if the receiver requires 50% of resolution, two subband signals may be selected from four subband signals, and the low frequency subband signal I1 in the vertical and horizontal directions is calculated in the order of the highest energy rank. The controller 400 will output a selection control signal so that a subband signal of a next energy rank is selected.

In addition, when the receiver requires 75% of resolution, three subband signals may be selected from four subband signals. The low frequency subband signal I1 in the vertical and horizontal directions is calculated in the order of the highest energy rank calculated above. The next two subband signals of the energy ranking will be selected. That is, the controller 400 outputs a selection control signal so that the remaining subband signals are selected except the subband signal having the lowest energy rank.

In general, when a resolution of 25%, 50%, or 75% is required, the low frequency subband signals I1, the low frequency and high frequency subband signals I2, I3, and the high frequency subband signal I4 are sequentially selected. According to the subband signal to be transmitted according to the energy ranking is selected.

Therefore, when the energy rank is the subband signal I1, the subband signal I3, the subband signal I2, and the subband signal I4, the subband signals are selected and transmitted in order of increasing energy. The picture quality is improved.

As described above, the adaptive gradual transmission system according to the present invention selectively subbands according to the resolution required by the receiver according to the energy rank determined using the average value and the second moment of the pixels in the block in the rectangular band division scheme. By selecting, the image quality of the reconstructed image can be improved for the same data rate.

Claims (3)

Rectangular band division filter means for filtering the input image signal by a rectangular band division scheme and outputting subband image signals, respectively; According to the resolution selection signal input from the outside, each subband video signal outputted from the rectangular band split filter means is input, and the energy rank of each subband using the average value and the second moment of the pixels in each subband. Control means for outputting a selection control signal so as to select a subband signal by selecting? And And selecting means for selecting and outputting a subband video signal outputted from the rectangular band split filter means. The method of claim 1, wherein the rectangular band split filter means A first low pass filter unit for low pass filtering and sampling the input image signal in one dimension; A second low pass filter unit for filtering and sampling the output of the low pass filter unit in one-dimensional low pass to output the low frequency subband signals in the vertical and horizontal directions to the selection means; A first high pass filter unit for filtering and sampling the output of the low pass filter unit in one-dimensional high pass to output high frequency and low frequency subband signals in the vertical and horizontal directions to the selection means; A second high pass filter unit for high pass filtering and sampling the input image signal in one dimension; A third low pass filter unit for filtering and sampling the output of the high pass filter unit in one-dimensional low pass to output the high frequency and low frequency subband signals in the vertical and horizontal directions to the selection means; And And a third high pass filter for outputting the high frequency subband signal in the vertical and horizontal directions to the selecting means by filtering and sampling the output of the high pass filter in one-dimensional high pass. The method of claim 1, wherein the energy rank is Each subband video signal output from the rectangular band splitting filter means is first determined by comparing energy magnitudes according to an average value of pixels of each divided block of each subband calculated as an input, and the subband division is determined. Wherein if the average value of the pixels of each block is less than or equal to the set average threshold, the calculated second moment of each block of the corresponding subband is secondarily determined by the number of blocks or more than the set moment threshold or the average value of the pixels of the block. Progressive transmission system.