KR20010058723A - Driving device and method of AC plasma display panel - Google Patents

Abstract

PURPOSE: A device and a method for driving an AC type plasma display panel are provided to remove a pseudo outline easily by detecting a pseudo outline area and compensating the pseudo outline area at the same time through comparing the previous frame data and the present frame data. CONSTITUTION: A device for driving an AC type plasma display panel includes an input part(300), a data control part(330), a frame memory part(310), a memory control part(320), a time delay part(340), a compare part(350), a detecting part(360), a look up table(370), and an operating part(380). The input part(300) receives digital video signals sequentially. The data control part(330) controls that the digital video signals are transmitted to the frame memory part(310) and the compare part(350). The frame memory part(310) stores frame data. The memory control part(320) controls a storage sequence of the frame data at the frame memory part(310). The time delay part(340) waits for a previous data before the previous frame data and a present frame data are transmitted to the compare part(350). The compare part(350) confirms whether there is a pseudo outline area by comparing the previous frame data and the present frame data or not. The detecting part(360) detects a compensation delay, a compensation direction, and a compensation speed of the two frame data. The look up table(370) includes a compensation numerical value for compensating a pseudo outline. The operating part(380) compensates the pseudo outline by using delay time data about compensation, direction data, and data of the look up data(370).

Description

AC type plasma display panel driving device and method {Driving device and method of AC plasma display panel}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for driving a plasma display panel (hereinafter referred to as PDP), and more particularly, to an apparatus and method for removing pseudo contours of an AC-type three-electrode surface discharge PDP.

As is well known, a PDP is a device that displays characters or graphics by using light emitted from a plasma generated during gas discharge. PDP has the advantage of being most suitable for large-scale display among various flat panel displays such as liquid crystal display (LCD), field emission display (FED), and electroluminescence display (ELD), which are being actively studied.

That is, the plasma display panel can be enlarged to 40 "or more, and CRT level colorization is possible because the ultraviolet light generated by the discharge uses a photoluminescence mechanism that stimulates the fluorescent film and emits visible light. As a self-emissive display, it has many unique advantages that cannot be found in other flat panel devices such as having a wide view of more than 160 °. It is a multimedia that combines the functions of next-generation high-definition wall-mounted TV, TV, and PC. It is considered to be a large display device for use.

PDP uses two glass substrates with a thickness of about 3 mm to apply an appropriate electrode and phosphor on each substrate, and forms plasma in the space therebetween while maintaining the distance between the two substrates at about 0.1 mm to 0.2 mm. Since it is adopted, it can be enlarged as a flat plate. In addition, in the PDP, the gas discharge has a strong non-linearity in which discharge does not occur even when a voltage is applied between electrodes, and a super large panel having a memory function that is essential for driving a large display. Even in this case, a high quality image can be expressed without deteriorating the luminance.

Currently, AC type three-electrode surface discharge PDPs using an ADS (Address Display Seperating) drive method are widely known among various models of the PDP.

As is well known, the AC-type three-electrode surface discharge PDP is provided with three types of electrodes, that is, a sustain electrode (X electrode), a write / hold electrode (scan electrode or Y electrode), and an addressing electrode. In order to maintain the discharge of the selected cell for display among the plurality of unit cells by applying a high voltage (for example, 180V to 300V) of the positive and negative (+,-) alternately provided in each unit cell of the PDP The write / sustain electrode performs a function of maintaining a discharge of a selected cell together with the sustain electrode when writing data and holding a cell, and the addressing electrode each receives an address signal for addressing data. Perform the function provided to the cell.

1 is a conventional method for driving a three-electrode, surface discharge, and alternating type PDP. Each subfield uses a gray scale display method using a time division method and a display method using a time division method within a field. It is shown. In this case, since the write display discharge period and the sustain discharge period are separated, it is called an ADS (Address-Display-Seperating) method.

The subfield method of the ADS driving method will be briefly described with reference to FIG.

Considering the human eye's discrimination ability, about 256 halftone display capability is required in high-definition display. Accordingly, in the case of AC PDP, if one frame is composed of frames without interference with each other, and one field is desired to be displayed with gray scale of 256 gray levels, one field is divided into eight subfields. The length of the light emission time of each subfield is divided by (subfield) to 1 (= 2 ⁰ ): 2 (= 2 ¹ ): 4 (= 2 ² ): 8 (= 2 ³ ): 16 (= 2 ⁴ ): 32 (= 2 ⁵ ): 64 (= 2 ⁶ ): 128 (= 2 ⁷ ) By dividing so that the desired 256 gradations can be obtained, and each is called SF1 to SF8. In addition, each of the SF1 to SF8 is divided into a reset section 10, an address section 20, and a sustain discharge section 30.

Here, in order to obtain the luminance 1, the SF1, the luminance 2 are the SF2, and the luminance 3 is 256 gray levels using the same method as the SF1, the bit SF2, ....

However, in the PDP using the ADS driving method, since there is no display method other than the off and on states of each pixel, the PDP using the ADS driving method can be represented by the method of maintaining the off and on states of the pixels. Therefore, due to the preconditions described above, there is no choice but to use a method in which the human eye obtains a desired luminance by integrating brightness over time.

This is the fundamental reason why pseudo contours occur in PDP operation.

The reason why the pseudo contour is generated is to assume that the data of the first screen is displayed at a luminance of 127 (binary 0111-1111) and the display data of the second screen is displayed at 128 (binary 1000-0000) in a certain region. When the human eye is present between the display data 127 and 128 (1000-0000 / 0001-1111 when arranged in a row), the second screen is displayed by the first gray level subfield, which is turned off. It will appear darker than the screen.

In particular, when an area having a boundary between 127 and 128 moves on the screen, this phenomenon causes a dark appearance at the edge of the moving object 128. The unwanted border that appears here is called pseudocontour or false contour.

FIG. 2 is a view for explaining the cause of the pseudo contour in more detail. As shown in FIG. 2, when the frame having the luminance display of 128 is moved to the right side from the background screen having the luminance display of 127, the portion 'A' and FIG. Unwanted parts like 'B' will appear. That is, the portion 'A' is a portion to be changed to a screen having the luminance display of 127 while the frame having the luminance display of 128 is moved to the right side, and the portion having the luminance display of the 128 is the right portion of the 'B' portion. While moving to, the screen corresponding to the luminance of 127 is to be changed to the screen corresponding to the luminance of 128.

However, the 'A' portion should be expressed with a luminance corresponding to 127, that is, darker than the luminance corresponding to 128. On the screen, the luminance closer to 128, that is, lower than the luminance of 127, is expressed. Similarly, the 'B' portion should be expressed as a brightness brighter than 128, that is, a brightness corresponding to 127. On the screen, the brightness less than the brightness of 128 is expressed.

There are two main ways to remove the pseudo contour as described above.

First, after detecting the contour of a moving object, the data of the edge is compared with the surrounding screen data, and the data of the edge is not darker or brighter than the surrounding data, or the outline, that is, the edge is blurred. It is a way to remove the contour by floating it.

Secondly, it is assumed that the cause of the above pseudo contour is caused by the number of '0' (undisplayed subfields) interposed between the display data, and the data of the edge of the pseudo contour is 1000-0000 / There is a method of removing pseudo contours by inserting correction data 0111-1111 / 0000-0000 between 0111-1111.

Specifically, the first method is called an error diffusion method, and is also called an indirect method because the pseudo contour is removed by changing or mixing parts where the pseudo contour is generated. The second method is called an equalizing pulse method, and is also called a direct method since the pseudo contour is removed by inserting data that can find and correct the data of the part where the pseudo contour is generated.

However, the indirect method is the most well known and implemented, but because it is not to find the cause and eliminate or correct the problem, but to make the problem part in the middle of each other, when the screen is viewed, the edges are mosaic-like. A problem that looks like this is occurring.

In addition, although the above-mentioned direct method (Equalizing Pulse Method) is not mentioned above, since the degree of pseudo contour has many considerations such as the speed, direction of movement of the frame, the thickness and strength of the unwanted edges, There are many problems so far because it is necessary to extract the exact figures.

The present invention has been made to solve the above-described problems, and compares the image data of the previous frame stored in the frame memory with the current image data to detect an area where pseudo contours can occur, and the movement direction of this area. And by detecting the speed and compensating according to the data, the direction and the speed based on the data set in advance, thereby providing a PDP capable of suppressing the occurrence of pseudo contours and obtaining an improved image.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing each subfield by an ADS driving method of an AC type three-electrode surface discharge PDP according to the prior art.

Figure 2 is a view for explaining in more detail the cause of the pseudo contour occurs.

3 is a block diagram of a system for removing pseudo contours in accordance with an embodiment of the present invention.

In order to achieve the above object, the present invention divides one frame into a plurality of subfields, and divides each subfield into a reset section, an address section, and a sustain discharge section, thereby displaying an image according to a selective write discharge of the discharge cell. A pseudo contour removal apparatus for a three-electrode surface discharge AC plasma display panel to be displayed, comprising: memory means for storing frame data sequentially input having an size of 8 bits provided from the outside; a previous frame stored in the memory means Comparison means for confirming whether or not a pseudo contour area by comparing data and frame data currently input; Detection means for receiving data of the comparison means and detecting data in the pseudo contour portion by time delay, direction, and speed; And calculating means for receiving the data of the detecting means and calculating the calculated data to compensate for the pseudo contour area.

Also, the present invention preferably divides one frame into a plurality of subfields, and divides each subfield into a reset section, an address section, and a sustain discharge section to display an image according to the selective write discharge of the discharge cells. A pseudo contour removal method of an electrode surface discharge AC plasma display panel, comprising: a first step of storing frame data having a size of 8 bits sequentially input from the outside; A second step of identifying a pseudo contour area by simultaneously comparing the stored previous frame data with currently input frame data; A third step of detecting data by dividing the pseudo contour area identified in the second step by time delay, direction, and speed; And a fourth step of outputting the compensated data by calculating each of the data of the third step.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the technical idea of the present invention. do.

3 is a block diagram of a system for removing pseudo contours in accordance with an embodiment of the present invention.

As shown, the input unit 300 sequentially inputs a digital video signal having a size of 8 bits each of R (Red), G (Green), and B (Blue), and a frame memory unit and a comparator receiving the digital video signal. Data control unit 330 for controlling sending to, frame memory unit 310 that can store the frame data, the storage in the frame memory unit 310, for example to store the first data and the second data to be stored separately The memory controller 320 controls the time delay unit 340 and the first data and the second data to wait for the first data stored in the frame memory unit 310 before the first data and the second data enter the comparator. Comparing unit 350 to check whether the pseudo contour region can occur by comparing, two depart from the comparison unit 350 Detecting unit 360 for measuring compensation delay, direction or speed of the data, a lookup table 370 in which a preset compensation value is input to compensate for pseudo contours related to the velocity measured by the detecting unit 360. And an operation unit 380 that compensates an area in which a pseudo contour occurs by receiving and calculating delay time data according to the compensation from the detection unit 360, compensation data for a direction, and data from the lookup table 370. This has been.

It will be described in detail the operation of the pseudo contour removal apparatus according to an embodiment of the present invention having the configuration as described above.

Here, the digital video signal is divided into two types of first frame data and second frame data for easy description. The pseudo contour removal apparatus according to the embodiment of the present invention corresponds to each of R (Red), G (Green), and B (Blue), but only R (Red) will be described herein.

First, the input unit 300 receives first frame data having a size of 8 bits input from the outside.

Next, the first frame data is divided into two places in the data control unit 330, and since the first frame data is the first screen, it is not necessary to consider the pseudo contour, so the output is just output. It is stored in the frame memory unit 310 for comparison with two frame data. Here, the frame memory unit 310 is divided into two, a first frame memory 311 and a second frame memory 312. Under the control of the memory controller 320, the first frame memory 311 includes the The first frame data is stored, and the second frame data is stored in the second frame memory 312.

Next, the second frame data is input through the input unit 300 to be input to the delay unit 340 and the data control unit 330. The second frame data inputted to the data controller 330 is used by the memory controller 320 to compare with the next frame data to be input into the second frame memory 312 of the frame memory unit 310. It is stored in.

Next, the data control unit 330 stores the first frame data stored in the first frame memory 311 to compare pseudo contours between the first frame data entered first and the second frame data entered next. Through the control of the output to the comparator 350. In this case, the second frame data that has been delayed by the time delay unit 340 is also input to the comparison unit 350.

Next, the comparison unit 350 checks whether the first contour data and the second frame data generate pseudo contours, and outputs the pseudo contours only when the pseudo contours do not occur, and when the pseudo contours occur, the detection unit. Input is 360.

The detector 360 is divided into three parts: a time compensator 361 for delayed time compensation, a direction part 362 for measuring directions of the two signals, and a speed part 363 for speed measurement. Here, the time compensator 361 detects pseudo contour data represented by a time difference between the first frame data and the second frame data, and the direction part 362 detects the first frame data and the second frame data. The direction of movement of the frame corresponding to the measurement is measured, and the speed unit 363 measures the speeds of the first frame data and the second frame data and inputs the compensation value to the lookup table 370 in which the compensation value is preset. Will output the data.

Finally, the data from each of the time compensator 361, the direction part 362, and the lookup table 370 is inputted from the calculator 380 to perform an operation to compensate for an area in which a pseudo contour is generated.

Although the technical idea of the present invention has been described in detail according to the above preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

PDP pseudo contour removal apparatus according to an embodiment of the present invention as described above, by comparing the previous frame data and the current frame data at the same time to detect the pseudo contour region and compensation in consideration of the direction and speed to implement the pseudo contour removal It has an easy effect.

Claims (8)

A three-electrode surface discharge alternating current plasma display for dividing and driving one frame into a plurality of subfields and dividing each subfield into a reset section, an address section, and a sustain discharge section to display an image according to a selective write discharge of the discharge cells. In the pseudo contour removal device of the panel, Memory means for storing frame data sequentially input having an size of 8 bits provided from the outside; Comparison means for confirming whether or not a pseudo contour area is compared by simultaneously comparing previous frame data stored in the memory means and currently input frame data; Detection means for receiving data of the comparison means and detecting data in the pseudo contour portion by time delay, direction, and speed; And Calculation means for outputting data for compensating the pseudo contour area by receiving and calculating each data of the detection means Pseudo contouring device of the plasma display panel comprising a. The method of claim 1, The memory means is divided into a first memory and a second memory, wherein previous frame data is stored in the first memory, and frame data following the previous frame data is stored in the second memory. Pseudo contouring device. The method of claim 1, And a delay means for compensating a temporal difference between the previous frame data stored in the memory means and the currently input frame data. The method of claim 1, And said detecting means further comprises a look-up table to which a compensation value which is set in advance is compensated for compensating the pseudo contour according to the speed. A three-electrode surface discharge alternating current plasma display for dividing and driving one frame into a plurality of subfields and dividing each subfield into a reset section, an address section, and a sustain discharge section to display an image according to a selective write discharge of the discharge cells. In the method of removing the pseudo contour of the panel, A first step of storing frame data having a size of 8 bits sequentially input from the outside; A second step of identifying a pseudo contour area by simultaneously comparing the stored previous frame data with currently input frame data; A third step of detecting data by dividing the pseudo contour area identified in the second step by time delay, direction, and speed; And A fourth step of outputting the compensated data by calculating each of the data of the third step Pseudo contour contour removal method of the plasma display panel comprising a. The method of claim 5, The frame data storage in the first step is divided into two parts to store the frame data consecutive to each other, the contour contour removal method of the plasma display panel. The method of claim 5, And removing the contour outline of the plasma display panel by delaying the current frame data in the second step and simultaneously comparing the stored previous frame data. The method of claim 5, The method of claim 3, wherein the velocity detection data is input to a look-up table having a preset compensation value to compensate for the velocity.