KR100421482B1 - Apparatus and Method of Processing Video Signal in Plasma Display Panel - Google Patents

Abstract

The present invention relates to an image signal processing method and apparatus for a plasma display panel capable of preventing color distortion caused by different afterglow time for each phosphor.

The video signal processing method of the plasma display panel includes the steps of: preparing a weight of each bit of the video data and the weight of the afterglow time of each phosphor on the surrounding pixels in a table form; Generating display image data which is actually implemented in the panel using the input first video data; Detecting a first compensation value by comparing the display video data with the delayed first video data; Calculating a maximum compensateable maximum compensation value from the first video data; Comparing the first compensation value with the maximum compensation value, one of them is selected and the final compensation value for the previous pixel fed back to the selected compensation value is added as a weight value affecting the surrounding pixels and output as the final compensation value. And allowing feedback; And outputting the compensated data by adding the final compensation value to the delayed first video data.

Description

Apparatus and Method of Processing Video Signal in Plasma Display Panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving technology of a plasma display panel, and more particularly, to a method and apparatus for processing an image signal of a plasma display panel capable of preventing color distortion caused by different afterglow time for each phosphor.

Recently, a plasma display panel (hereinafter referred to as PDP) has attracted attention as a thin and lightweight display device. In the case of displaying a video signal (for example, a television signal) with this PDP, a modulation method is generally used in which the number of emission is proportional to the video signal. Specifically, the video signal is digitized and each frame period is divided into subfield periods corresponding to the number of bits of the digitized video data. In each subfield period, gradation display is performed by emitting light a number of times proportional to the weight of digital video data.

For example, when an image is displayed in 256 gray scales using 8-bit video data, one frame display period (for example, 1/60 second = about 16.7 msec) in each pixel is divided into eight sub-frames as shown in FIG. It is divided into field periods SF1 to SF8. Each subfield period SF1 to SF8 is further divided into a reset period RP, an address period AP and a display period SP, and the display period SP is 1: 2: 4: 8:... The weight is given at the ratio of 128. The reset period RP and the address period AP are equally allocated to each subfield period. In this PDP driving method, the display order of subfield periods corresponding to each bit is in a constant order as in the example of SF1, SF2, SF3, SF4, SF5, SF6, SF7, SF8. Since the subfield periods are arranged in a certain order, the display period and the non-display period are distributed in various forms in one frame period according to the logic value of the pixel. In this way, the display period and the non-display period are dispersed in one frame, and the display order of the subfield periods SF1 to SF8 becomes constant, resulting in contour noise in the display image.

The PDP displays an image by superimposing light emitted in each subfield period in a pulse width modulation scheme. In this PDP driving method, contour noise occurs due to the mismatch between the direction of integration of light and visual characteristics recognized by the human eye. Contour noise is usually observed in the form of white or black bands between frames. For example, when gradation levels with greatly differing light emission patterns such as 127-128, 63-64, 31-32, etc. are displayed continuously, contour noise occurs between frames.

In the case of the frame changing from 128 to 127, the difference in brightness level between the two frames is not large, but the time difference between the light emission patterns is large, resulting in a large shift of the light emitting point. In this case, since the eye does not follow this light emitting point but moves along a straight line in the direction of the arrow as shown in FIG. 2, a bright band is actually observed between two frames. In the case of the frame changing to 127-128, black bands are observed due to the same cause. This contour noise is most often found when moving flesh-colored objects, and thus is often found in moving images of human faces and body parts. In addition, when displaying a color image, the color balance is degraded due to the contour noise.

FIG. 2 shows the amount of pseudo contours that are actually recognized in the human retina. In particular, FIG. 2 shows gradation values of images displayed on the retina when three pixels of 127 and 128 images move to the left. In FIG. 2, W0 to W6 refer to positions where pixels displayed on the PDP are actually recognized in the retina.

In FIG. 2, it can be seen that light emission corresponding to each bit affects not only the position W0 recognized by the retina, but also the next position W1 recognized by the retina. Accordingly, when the gray scale value is changed from 127 to 128, the gray scale value recognized at the positions of W3, W4, and W5, which are the boundary portions 127 and 128, is significantly lowered to 55.67, 29.33, and 114.3. As a result, a pseudo outline phenomenon in the form of black lines occurs at the boundary between 127 and 128 frames.

In order to eliminate such pseudo contouring, an error diffusion method and an equalization pulse method have been proposed.

In the error diffusion method, a pseudo intermediate gray scale is generated by using luminance differences due to characteristics of eight subfields and 256 gray scales, that is, error data. Then, the error data calculated to express the pseudo halftone are distributed to adjacent pixels with different weights. Since the error diffusion is implemented by adding error diffusion data to the original 8-bit data, 12 or more subfields are required. As a result, the address period is increased in the period of one frame, and the luminance is lowered due to the decrease between the relative sustain discharges.

The equalization pulse method is a method of compensating the image actually displayed similarly to the original data by increasing or decreasing the data of the point generating the pseudo contour as shown in FIG. 3. In the case of controlling for the increase or decrease of data, the influence of light emission of each bit on the current pixel and the next pixel with respect to the motion vector should be used. The weight of each bit emission on the adjacent pixel with respect to the motion vector is shown in Table 1 below.

W1 W2 W3 W4 B0 One 0 0 0 B1 2 0 0 0 B2 4 0 0 0 B3 8 0 0 0 B4 16 0 0 0 B5 31.4 0.6 0 0 B6 8.929413 55.070587 0 0 B7 0 29.329411 85 13.670588 SUM 71.329413 84.999998 85 13.670588

As shown in Table 1, by increasing (or decreasing) the data of the point generating the pseudo contour as shown in FIG. Similar compensation is given.

This equalization pulse method can be implemented by an image processing apparatus as shown in FIG. 4 disclosed in Japanese Patent Laid-Open No. 10-039828.

The image processing apparatus shown in FIG. 4 is a luminance adjustment block including a frame memory 310 for delaying vertical synchronization period (1V) of input data, an equalization pulse determination circuit 410, and an equalization pulse addition circuit 420. 400. The equalization pulse determination circuit 410 includes a comparator 410a and a lookup table (LUT: ROM) 410b. The comparison unit 410a compares the bit data of the n-th frame 230 with the bit data of the n + 1 th frame following the n-th frame, and +1, for a bit in which the bit data is turned on and not lit. Outputs -1 for a bit that is lit with no lighting and 0 for a bit that does not change data between both frames. The LUT 410b is configured as a ROM to which predetermined data is written in advance, and generates a predetermined equalization pulse in accordance with the output of the comparing unit 410a. The equalization pulse output from this LUT 410b has a sign of government. The adder 420 adds an equalization pulse (signal of the government) to the original signal 210, and outputs the display signal 220 after the equalization pulse is added or subtracted.

As described above, the conventional equalization pulse method minimizes pseudo contours by compensating for brightness by increasing or decreasing the amount of data generating pseudo contours.

However, the image distortion problem remains in the PDP despite the conventional pseudo contour removal method. This is because the color distortion occurs as the afterglow time of the phosphors used in the PDP varies by color as shown in Table 2 below.

Phosphor 1 / e afterglow time [ms] Y ₂ O ₃ : Eu ^{3 =} (R) 1.3 Y _0.65 Gd _0.35 BO ₃ : Eu ^{3 =} (R) 4.3 Zn ₂ SiO ₄ : Mn (G) 11.9 BaAl ₁₂ O ₁₉ : Mn (G) 7.1 BaMg ₂ Al ₁₄ O ₂₄ : Eu ^{2 =} (B) 0.001

As shown in Table 2, the afterglow time of the phosphor is different for each color. In particular, it can be seen that the green phosphor (G) has a relatively long afterglow time compared to the other phosphors (R, B). Different afterglow times of the phosphors R, G, and B appear as a distortion phenomenon in the image with the movement. In fact, when the white and black boundary moves, the green band is generated by the green phosphor G having a relatively long afterglow time at the boundary. The image distortion caused by the difference in the afterglow time of the phosphor becomes more serious as the movement increases.

Accordingly, it is an object of the present invention to provide a method and apparatus for processing a video signal of a PDP capable of preventing color distortion caused by different afterglow time for each phosphor.

1 is a diagram showing a frame driving form according to a conventional PDP driving method.

2 is a view for explaining the principle of generating a pseudo contour in the conventional PDP driving method.

3 is a view for explaining a conventional equalization pulse method.

4 is a block diagram of an image processing apparatus for implementing a conventional equalization pulse method.

5 is a diagram schematically illustrating an apparatus for processing a PDP video signal according to an embodiment of the present invention.

6 is a diagram schematically illustrating an apparatus for processing a PDP video signal according to another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10, 24: display image generator 12, 18, 22, 34: buffer

13, 26: subtractor 14, 30: maximum compensation detector

16, 32: compensation value determiner 20, 36: adder 28: supervisor 310: frame memory 400: luminance adjustment block 410: equalization pulse discrimination circuit 410a: comparator 410b: lookup table 420: adder

In order to achieve the above object, a video signal processing method of a PDP according to an aspect of the present invention comprises the steps of providing a weight of the brightness of each bit of the video data and the afterglow time of each phosphor in the form of a table; Generating display image data which is actually implemented in the panel using the input first video data; Detecting a first compensation value by comparing the display video data with the delayed first video data; Calculating a maximum compensateable maximum compensation value from the first video data; Comparing the first compensation value with the maximum compensation value, one of them is selected and the final compensation value for the previous pixel fed back to the selected compensation value is added as a weight value affecting the surrounding pixels and output as the final compensation value. And allowing feedback; And outputting the compensated data by adding the final compensation value to the delayed first video data.

According to an aspect of the present invention, an apparatus for processing a video signal of a PDP provides a table with weights of luminance of each bit of video data and afterglow time of each phosphor on a peripheral pixel, and converts the first video data into a weight table. A display image generator for generating display image data which is actually implemented in the panel by using; A first delayer for delaying the input first video data by a first period; A subtractor for comparing the display image data with first video data delayed by the first delayer to detect a first compensation value; A maximum compensation value detector configured to calculate a maximum compensateable maximum compensation value from the input first video data; Comparing the first compensation value with the maximum compensation value, one of them is selected and the final compensation value for the previous pixel fed back to the selected compensation value is added as a weight value affecting the surrounding pixels and output as the final compensation value. And a compensation value determiner for feeding back; A second delayer for delaying the input first video data by a second period; And an adder configured to output the compensated data by adding the final compensation value to the first video data delayed by the second delayer.

Other objects and features of the present invention in addition to the above object will be apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 5 and 6.

5 is a block diagram schematically illustrating an image signal processing apparatus of a PDP according to an exemplary embodiment of the present invention. The image signal processing apparatus of the PDP shown in FIG. 5 includes a display image generator 10, first and second buffers 12 and 18, a maximum compensation value detector 14 connected to a data input line 11, A subtractor 13 commonly connected to the output terminal of the first buffer 12 and the display image generator 10, and a compensation value determiner 16 commonly connected to the output terminal of the subtractor 13 and the maximum compensation value detector 14. ) And an adder 20 commonly connected to the output terminals of the second buffer 18 and the compensation value determining unit 16.

The display image generator 10 inputs original video data through the data input line 11 to generate display image data that is actually displayed in consideration of the effect of emission of each bit, that is, luminance and phosphor afterglow time on surrounding pixels. do. To this end, the display image generator 10 has a weight table in which a weight table is given in accordance with the magnitude of the influence of luminance and R, G, B phosphor afterglow time on the surrounding pixels, similar to a conventional equalization pulse method. Is built into. The display image generator 10 converts the original video data input by using the weight table into the display image data actually displayed for each bit. The first and second buffers 12 and 18 delay the original video data input through the input line 11 for synchronization with the display image data output from the display image generator 10. The subtractor 13 calculates a difference between the original video data delayed in the first buffer 12 and the display image data from the display image generator 10 and outputs a compensation value to be compensated to prevent luminance and color distortion. do. The maximum compensation value detector 14 inputs original video data through the data input line 11 to calculate and output the maximum compensable maximum value from the video data. The compensation value determiner 16 compares the compensation value from the subtractor 13 with the maximum compensation value from the maximum compensation value detector 14, and determines one of them as the first compensation value and outputs it. In other words, the compensation value determiner 16 outputs the first compensation value when the compensation value from the subtractor 13 is larger than the maximum compensation value, while the compensation value from the subtractor 13 is output. If smaller than the maximum compensation value, the compensation value from the subtractor 13 is output as the first compensation value. In addition, the compensation value determiner 16 adds a final compensation value for the previous pixel fed back to the first compensation value as a weight value that affects neighboring pixels and outputs the final compensation value. This final compensation value is fed back to weight the compensation value of the next pixel. The adder 20 adds the final compensation value from the compensation value determiner 16 to the original video data delayed in the second buffer 18 to compensate the luminance and color distortion compensation data through the output line 21. Output to the data driver. Accordingly, since the luminance and color distortion-compensated video data are supplied to the PDP through the data driver, it is possible to eliminate image distortion due to the difference in contour noise and phosphor afterglow time.

6 is a block diagram schematically illustrating an apparatus for processing a video signal of a PDP according to another embodiment of the present invention. The image signal processing apparatus of the PDP shown in FIG. 6 includes a display image generator 24, first and second buffers 22 and 34, a maximum compensation value detector 30 connected to a data input line 23, A subtractor 26 commonly connected to the output terminal of the first buffer 22 and the display image generator 24, and a compensation value determiner 32 commonly connected to the output terminal of the subtractor 26 and the maximum compensation value detector 32. ), An adder commonly connected to the supervisor 28 commonly connected to the display image generation unit 24 and the compensation value determination unit 32, and to an output terminal of the second buffer 34 and the compensation value determination unit 32. 35 is provided.

The supervisor 28 detects a motion vector by comparing the original video data input through the data input line 23 with previous frame data. The display image generator 24 inputs original video data through the data input line 23 to determine the effect of light emission, that is, luminance and R, G, and B phosphor afterglow time on the surrounding pixels. The display image data which is actually displayed is generated in consideration of the motion vector from the (). To this end, the display image generator 24 includes a weight table in the form of a ROM, which is weighted according to the magnitude of the influence of the luminance and the phosphor afterglow time on the surrounding pixels, similar to the conventional equalization pulse method. The display image generator 24 converts the original video data input by using the weight table and the motion vector from the supervisor 24 into the display image data actually displayed for each bit. The first and second buffers 22 and 34 delay the original video data input through the input line 23 to be synchronized with the display image data output from the display image generator 24. The subtractor 26 calculates a difference between the original video data delayed in the first buffer 22 and the display image data from the display image generator 24 and outputs a compensation value to be compensated to prevent luminance and color distortion. do. The maximum compensation value detector 30 inputs original video data through the data input line 23 to calculate and output the maximum compensable maximum value from the video data. The compensation value determiner 32 compares the compensation value from the subtractor 26 with the maximum compensation value from the maximum compensation value detector 30, and determines one of them as the first compensation value and outputs the first compensation value. In other words, the compensation value determiner 32 outputs the first compensation value when the compensation value from the subtractor 26 is greater than the maximum compensation value, while the compensation value from the subtractor 26 is output. If smaller than the maximum compensation value, the compensation value from the subtractor 26 is output as the first compensation value.

In addition, the compensation value determiner 16 adds a final compensation value for the previous pixel fed back to the first compensation value as a weight value that affects neighboring pixels and outputs the final compensation value. This final compensation value is fed back to weight the compensation value of the next pixel. The adder 36 adds the final compensation value from the compensation value determiner 32 to the original video data delayed in the second buffer 34 to output compensation data whose luminance and color are compensated through the output line 21. Will output to the driver. Accordingly, since the luminance and color distortion-compensated video data are supplied to the PDP through the data driver, it is possible to eliminate image distortion due to the difference in contour noise and phosphor afterglow time.

As described above, in the image processing method and apparatus of the PDP according to the embodiment of the present invention, the contour noise by performing the color correction in consideration of the afterglow time that is different for each of R, G, and B phosphors with luminance correction considering contour noise It is possible to eliminate image distortion caused by the difference in phosphor afterglow time.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (6)

Providing weights of the brightness of each bit of the video data and the afterglow time of each phosphor on the surrounding pixels in a table form; Generating display image data which is actually implemented in the panel using the input first video data; Detecting a first compensation value by comparing the display video data with the delayed first video data; Calculating a maximum compensateable maximum compensation value from the first video data; Comparing the first compensation value with the maximum compensation value, one of them is selected and the final compensation value for the previous pixel fed back to the selected compensation value is added as a weight value affecting the surrounding pixels and output as the final compensation value. And allowing feedback; And outputting the compensated data by adding the final compensation value to the delayed first video data. The method of claim 1, Detecting the motion vector by comparing the input first video data with data of a previous frame; The generating of the display image may include generating the display image in consideration of the motion vector. The method of claim 1, The maximum compensation value is selected when the final compensation value is greater than the first compensation value and the maximum compensation value. And the first compensation value is selected if the first compensation value is smaller than the maximum compensation value. A display for generating display image data that is actually implemented in a panel using the weight table by providing the weights of the brightness of each bit of the video data and the afterglow time of each phosphor on the surrounding pixels in a table form. An image generator; A first delayer for delaying the input first video data by a first period; A subtractor for comparing the display image data with first video data delayed by the first delayer to detect a first compensation value; A maximum compensation value detector configured to calculate a maximum compensateable maximum compensation value from the input first video data; Comparing the first compensation value with the maximum compensation value, one of them is selected and the final compensation value for the previous pixel fed back to the selected compensation value is added as a weight value affecting the surrounding pixels and output as the final compensation value. And a compensation value determiner for feeding back; A second delayer for delaying the input first video data by a second period; And an adder configured to output the compensated data by adding the final compensation value to the first video data delayed by the second delayer. The method of claim 4, wherein And a supervisor configured to detect the motion vector by comparing the input first video data with data of a previous frame, And the display image generating unit generates the display image in consideration of the motion vector. The method of claim 4, wherein The final compensation value determiner If the first compensation value and the maximum compensation value is greater than the maximum compensation value is selected, And if the first compensation value is smaller than the maximum compensation value, the first compensation value is selected.