KR20000000983A - System to gradually transmit sub-band - Google Patents

Abstract

PURPOSE: A system to gradually transmit sub-band is provided to improve display quality of an image. CONSTITUTION: The system comprises band division filters of orthogonal type and diamond type, a selector(500) and a controller(400). The band division filters of orthogonal type output negative band signals by filtering of orthogonal band division type. The band division filters of diamond type output negative band signals by filtering of diamond band division type. The selector(500) selects and outputs a negative band signal from the output signals. The controller(400) controls the selector(500) according to a resolution selection signal from external.

Description

SUBBAND PROGRESSIVE TRANSMISSION SYSTEM

The present invention relates to a subband gradual transmission system that allows a receiver to select a resolution. In particular, the present invention relates to a subband for improving image quality at the same data rate by mixing a rectangular band splitting scheme and a diamond band splitting scheme. A progressive transmission system.

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 sub-band 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) using the 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 a receiver requires more resolution, that is, when a resolution of 50% or 75% is required, the high frequency band 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.

However, in the conventional gradual transmission system using the rectangular band-segmentation scheme, in order to obtain 50% resolution, the reduction of the original signal is noticeable since only a single coordinate is generated.

That is, in the conventional gradual transmission system using only the rectangular band division scheme, the original signal shown in FIG. 2 (a) is shown in FIG. 2 (b) when a short axis is generated for the vertical axis to obtain 50% resolution. There was a problem in that deterioration was noticeable when the signal was deformed and restored to the original signal.

An object of the present invention to improve the above problems is to provide a sub-bans gradual transmission system for improving the image quality for the same data rate by using a mixture of the rectangular band-division scheme and the diamond-type band division scheme.

In order to achieve the above object, the present invention is a rectangular band split filter means for outputting a subband signal by filtering the input signal in a rectangular band division method, and outputs a subband signal by filtering the input signal in a diamond band division method. Image quality can be improved according to a diamond band division filter means, a selection means for selecting and outputting a subband signal output from the rectangular band division filter means and the diamond filter means, and a resolution selection signal input from the outside. And a control means for controlling the selection of the selection means to provide a subband progressive transmission system.

1 is a block diagram of a general subband progressive transmission system

FIG. 2 is a diagram for describing frequency characteristics of the rectangular filter of FIG. 1. FIG.

3 is a block diagram of a subband progressive transmission system according to the present invention;

4 is a view for explaining the frequency characteristics of the diamond filter of FIG.

Explanation of symbols on the main parts of the drawings

200: rectangular band division filter unit

201, 203, 213: 1-D right angle low pass filter

205, 211, 215: 1-D right angle high pass filter

202, 204, 206, 212, 214, 216, 302, 312: compressor

300: diamond-type band division filter unit

301: Diamond Type Low Pass Filter

311 diamond type high pass filter

400 controller 500 selector

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

Subband gradual transmission system according to the present invention is composed of a rectangular band split filter 200, a diamond band split filter 300, a selector 500, and a controller 400 as shown in FIG. do.

The rectangular band split filter 200 is a one-dimensional rectangular low pass filter 201 for low-pass filtering the input signal x (z1, z2) in one dimension, and the one-dimensional rectangular low pass filter 201. Compressor 202 for sampling the output of the filter, one-dimensional rectangular low-pass filter 203 for one-dimensional low pass filtering the output of the compressor 202, the output of the one-dimensional rectangular low-pass filter 203 A compressor 204 for sampling, a one-dimensional rectangular high pass filter 205 for filtering the output of the compressor 202 in one dimensional high pass, and a compressor for sampling the output of the one-dimensional rectangular high pass filter 205 ( 206, a one-dimensional rectangular high pass filter 211 for high pass filtering the input signal x (z1, z2) in one dimension, and a compressor for sampling the output of the one-dimensional rectangular high pass filter 211 ( 212, a one-dimensional rectangular low-pass for filtering the output of the compressor 202 one-dimensional low pass And a filter 213, a compressor 214 for sampling the output of the one-dimensional rectangular low pass filter 213, and a one-dimensional high-pass filter 215 for one-dimensional high pass filtering the output of the compressor 212. And a compressor 216 for sampling the output of the one-dimensional rectangular high pass filter 215.

The diamond-type band division filter unit 300 outputs a subband signal by filtering the input signal x (z1, z2) by a diamond-type band division method, and diamonds the input signal x (z1, z2). Diamond-type low pass filter 301 for band-pass filtering by type and low-pass filtering, 1 compressor 302 for sampling output of diamond-type low pass filter 301, and input signal (x (z1, z2)) A diamond type high pass filter 311 for band-passing and high-pass filtering the type, and one compressor 312 for sampling the output of the diamond type high pass filter 311.

The selector 500 selects a subband signal output from the quadrature band split filter 200 and the compressors 204, 206, 214, 216, 302, and 312 of the diamond filter 300. Output, consisting of a multiplexer.

The controller 400 is for controlling the selection of the selection means 500 to improve the image quality according to a resolution selection signal input from the outside.

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

When the video signal x (z1, z2) to be coded and input is input, the rectangular band-division filter unit 200 filters the four subband signals I1, I2, I3, and I4 by filtering by the rectangular band-division method. The diamond-type band division filter unit 300 outputs two subband signals I5 and I6 by filtering in a diamond-type band division scheme.

A detailed operation of the rectangular band split filter 200 and the diamond band split filter 300 will be described below.

The input image signal x (z1, z2) is a rectangular low-pass in the one-dimensional rectangular low pass filter 201 and the one-dimensional rectangular high pass filter 211 of the rectangular band split filter unit 200, respectively. And high pass filtering.

The outputs of the one-dimensional rectangular low pass filter 201 and the one-dimensional rectangular high pass filter 211 are sampled and compressed by the compressors 202 and 212, and then again the one-dimensional rectangular low pass filter 203, 213 and one-dimensional rectangular high-pass filters 205 and 215, respectively.

That is, the signal filtered by the compressor 202 after being filtered by the one-dimensional rectangular low pass filter 201 is perpendicular to the one-dimensional rectangular low pass filter 203 and the one-dimensional rectangular high pass filter 205, respectively. After the type low pass and high pass filtered, they are sampled and compressed by the compressors 204 and 206 and output as the low frequency subband signals I1 and I2.

In addition, the signal filtered by the compressor 222 after being filtered by the one-dimensional rectangular low pass filter 211 is perpendicular to the one-dimensional rectangular low pass filter 213 and the one-dimensional rectangular high pass filter 215, respectively. After the type low pass and high pass filtered, they are sampled and compressed by the compressors 214 and 216 and output as high frequency subband signals I3 and I4.

As such, the four subband signals I1, I2, I3, and I4 output from the compressors 204, 206, 214, and 216 of the rectangular band split filter unit 200 each have a 25% resolution subband. As a signal, it is input to the selector 500.

In addition, while the input image signal x (z1, z2) is filtered by the rectangular band division filter unit 200, the diamond band division filter unit 300 receives the input image signal x (z1, z2). ) Is filtered using the diamond band division method.

That is, the input signal x (z1, z2) is band-divided into diamonds by the low pass filter 301 and the high pass filter 311 of the diamond, respectively, and then low pass filtered, and then the compressors 302 and 312. In each is compressed.

As such, the compressed and output signals from the compressors 302 and 312 are the low frequency subband signal I5 and the high frequency subband signal I6, each having a resolution of 50% and input to the selection unit 500. do.

On the other hand, when a resolution selection signal is input from the outside, the controller 400 controls the selection unit 500 accordingly to select and output a subband signal to have a corresponding resolution.

For example, when the receiver requires a resolution of 75%, the controller 400 accordingly causes the selector 500 to output subband signals I1, I2, and I3 output from the compressors 204, 206, and 214. Control to choose.

In addition, when the receiver requires a resolution of 25%, the controller 400 controls the selection unit 500 to select the subband signal I1 output from the compressor 204 accordingly.

In addition, when the receiver requires a resolution of 50%, the controller 400 controls the selection unit 500 to select the low frequency subband signal I5 of the diamond band split filter 300 accordingly.

At this time, the diamond filter (301, 311) of the diamond band split filter 300 has a frequency characteristic as shown in Figure 4, it is filtered to output the image transmitted to the diamond.

That is, the input image shown in Fig. 4A passes through a diamond filter having the frequency characteristics shown in Fig. 4B and is output as a filtered image as shown in Fig. 4C.

Therefore, when the receiver requires 50% of resolution, if the low frequency subband signals I1 and I2 filtered by the rectangular band division scheme are selected and outputted, as shown in FIG. Although deterioration occurs, deterioration of the original signal is reduced as shown in FIG. 4 by selecting and outputting the low frequency subband signal I5 filtered by the diamond band division method.

As described above, the subband progressive transmission system according to the present invention has an effect of improving image quality at the same data rate by mixing and filtering a rectangular band-division scheme and a diamond-type band dividing scheme.

Claims (3)

Rectangular band split filter means 200 for filtering the input signals x (z1, z2) by a rectangular band split scheme to output a subband signal; Diamond-type band division filter means 300 for filtering the input signal x (z1, z2) by a diamond-type band division method and outputting a subband signal; Selecting means (500) for selecting and outputting a subband signal outputted from the rectangular band split filter means (200) and the diamond filter means (300); And And a control means (400) for controlling the selection of the selection means (500) so as to improve the image quality according to a resolution selection signal input from the outside. The method of claim 1, wherein the rectangular band split filter means 200 A first one-dimensional rectangular low-pass filter 201 for low-pass filtering the input signal x (z1, z2) in one dimension; A first compressor (202) for sampling the output of the first one-dimensional rectangular low pass filter (201); A second one-dimensional rectangular low pass filter (203) for one-dimensional low pass filtering the output of the first compressor (202); A second compressor (204) for sampling the output of the second one-dimensional rectangular low pass filter (203); A first one-dimensional rectangular high pass filter (205) for one-dimensional high pass filtering the output of the first compressor (202); A third compressor (206) for sampling the output of the first one-dimensional rectangular high pass filter (205); A second one-dimensional rectangular high-pass filter 211 for high-pass filtering the input signal x (z1, z2) in one dimension; A fourth compressor (212) for sampling the output of the second one-dimensional rectangular high pass filter (211); A third one-dimensional rectangular low pass filter (213) for one-dimensional low pass filtering the output of the fourth compressor (202); A fifth compressor (214) for sampling the output of the third one-dimensional rectangular low pass filter (213); A third one-dimensional rectangular high pass filter (215) for one-dimensional high pass filtering the output of the fourth compressor (212); And And a sixth compressor (216) for sampling the output of the third one-dimensional rectangular high pass filter (215). The method of claim 1, wherein the diamond-shaped band dividing filter means 300 A diamond-like low pass filter 301 for band-passing the input signal x (z1, z2) into diamonds for low pass filtering; A first compressor (302) for sampling the output of the diamond shaped low pass filter (301); A diamond-like high pass filter 311 for band-passing the input signal x (z1, z2) into diamonds for high pass filtering; And And a second compressor (312) for sampling the output of said diamond shaped high pass filter (311).