KR20010046350A - Method for driving plasma display panel - Google Patents

Abstract

PURPOSE: A method for driving a plasma display panel is provided to reduce a voltage level of a scan pulse using an active particle generated during a total discharge during an address discharge by performing the total discharge in a reset period and the address discharge in an address period continuously by each block, after dividing a number of scan electrodes into N blocks. CONSTITUTION: A PDP comprises four scan electrodes(Y1-Y4) and four sustain electrodes(X1-X4), and four scan electrodes are blocked into the first and the second scan electrode block. At first, a common sustain electrode(com1) is made by connecting the sustain electrodes(X1,X2) to two scan electrodes(Y1,Y2) included in the first scan electrode block in common, and a common sustain electrode(com2) is formed by connecting the corresponding sustain electrodes(X3,X4) to the scan electrodes(Y3,Y4) included in the second scan electrode block in common. According to the method, a self erasing and a total discharge discharging a discharge cell formed on a cross region of the sustain electrode(X1,X2) and the scan electrodes(Y1,Y2) included in the first scan electrode block are performed to neutralize the corresponding discharge cell. Continuously, a scan pulse is applied to the scan electrodes included in the first scan electrode block, and a data pulse is applied only to a data electrode(D) corresponding to a cell to be turned on among cells constituted by the scan electrodes(Y1,Y2) in order to make an address discharge between both electrodes.

Description

Driving method for plasma display panel {Method for driving plasma display panel}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel (hereinafter referred to as a PDP) among display elements. In particular, the present invention relates to a plasma display panel (PDP) driving. It is about a method.

In order to explain the PDP driving method, first, the electrode arrangement of the PDP will be described.

1 is an electrode arrangement diagram of a three-electrode surface discharge PDP, which is one of the most commonly used AC PDPs.

The structure of a typical three-electrode surface discharge PDP maintains a discharge and a scan electrode group (3, Y ₁ , Y ₂ ,..., Y _N ) to which a scan pulse is applied during an address section as shown in FIG. 1. To cause sustain discharge between the sustain electrode group 4, X ₁ , X ₂ ,..., X _N , to which the discharge sustain pulse is applied, and the scan electrode 3 and the sustain electrode 4 of the selected line. The data electrode group 2, D ₁ , D ₂ ,..., D _{M to} which data pulses are applied, and a set of scan electrodes 3 as vertical electrodes and a data electrode 2 as sustain electrodes 4 are horizontal electrodes. The cells 5 are formed at the point where they intersect with each other, and these cells are gathered to form one plasma display panel.

The basic driving principle of each cell of the three-electrode surface discharge PDP configured as described above is to generate an address discharge between the scan electrode 3 and the data electrode 2 so that wall charges and space charges are generated therein, and then the scan electrode 3 ) And sustain electrode 4 cause sustain discharge to make the discharge gas into a plasma state to generate ultraviolet rays, and the ultraviolet rays excite the phosphor to generate visible light.

Specifically, as one of the PDP driving methods, a reset section for uniformly erasing all charge distribution states of all cells during PDP driving, an address section for forming wall charges and space charges in cells at specific positions ) And ADS (Address Display Separating) method that selectively writes and discharges by separating the address section and the sustain section for the discharge cells to be displayed. A conventional PDP driving method is described below.

FIG. 2 is an exemplary driving voltage waveform diagram applied to each electrode of the three-electrode surface discharge PDP. The common sustain electrode com is a sustain electrode group 4, X ₁ , X ₂ ,..., X _N. The sustain electrode groups 4, X ₁ , X ₂ ,..., X _N are connected to each other so as to receive a common voltage pulse.

First, in the reset section, as shown in FIG. 2, the front discharge and self erasing are performed by applying a high double voltage pulse to the common sustain electrode com of all the cells to discharge all the cells. The entire cell is neutralized so that there is no problem in the addressing operation of the interval.

In the address section, the addressing of the digital image signal corresponding to each cell proceeds sequentially. That is, scanning is performed by applying a scan pulse to arbitrary scan electrodes Y ₁ to Y _N , and data electrodes D ₁ to D corresponding to cells to be turned on among the cells configured by the scan electrodes Y ₁ to Y _{N. The} data pulse is applied only to _M ) to cause address discharge between both electrodes, and to generate wall charges and space charges inside the cell. When the above process is repeated for the _N scan electrodes Y ₁ to Y _N sequentially, all the cells are turned on or off according to the corresponding digital image signals. At this time, before performing a full-scale addressing operation, a predetermined low voltage is applied to each scan electrode to help address discharge.

When the address discharge is completed, in the sustain section, the sustain sustain pulse is alternately applied between the scan electrodes Y ₁ to Y _N and the common sustain electrode com to cause sustain discharge to occur, thereby turning on the previous address section. The image is displayed in the cell. At this time, gradation control of the image is performed by the number of sustain pulses.

Particularly, in the reset section of the PDP as described above, addressing the address section is performed by applying a double voltage pulse to the common sustain electrode com of all the cells to perform front discharge and self erasing to discharge all the cells. Neutralizes the entire cell so that there is no problem in operation, because when a single frame screen is driven by dividing into a plurality of subfield screens, the number of charged particles remaining in the cell through the sustain interval of the previous subfield is reduced. Since panels have non-uniform characteristics depending on the space, high voltages are applied to make these panels overall uniform.

On the other hand, in order to drive the PDP of the representative capacitance, the width of the scan pulse and the voltage of the pulse applied to the scan electrodes Y ₁ to Y _N for the address discharge of the address section are smaller for the high speed addressing operation. However, in the conventional PDP driving as described above, the amount of active particles and wall charges contributing to the address discharge is insufficient due to the rapid attenuation of the active particles generated during the front discharge of the reset section, so that the scan pulse in the address section is relatively high. It must have a voltage level and a pulse width above a certain time. As a result, the probability of occurrence of address discharge is lowered due to the low scan pulse voltage, and a reliable addressing operation is impossible, thereby degrading the display characteristics of the PDP.

In addition, since one frame screen is driven by being divided into a plurality of subfield screens, a scan pulse having a pulse width of a predetermined time or more must be applied due to a time constraint required for address discharge between the scan electrode and the data electrode according to each subfield. The number of scan electrodes is limited, which causes a lot of difficulty in realizing a high definition full color PDP by increasing the number of scan electrodes.

The present invention has been made to solve the above problems, by dividing a plurality of scanning electrodes into N blocks, each of the blocks to perform the front discharge in the reset section and the address discharge in the address section continuously generated during the front discharge It is an object of the present invention to provide a method of driving a plasma display panel for lowering the voltage level of a scanning pulse by using active particles during address discharge.

The present invention provides a method of driving a plasma display panel capable of high-definition PDP by reducing the pulse width of scan pulses applied during address discharge in an address section and increasing the number of addressable scan electrodes in an address section of each subfield. do.

1 is an electrode arrangement diagram of a three-electrode surface discharge PDP which is one of the most commonly used AC type PDP.

2 is an exemplary driving voltage waveform applied to each electrode of the three-electrode surface discharge PDP.

3 is a driving voltage waveform diagram according to an embodiment of the present invention applied to each electrode of the PDP.

According to the present invention for achieving the above object, a plurality of third (N is a natural number) first and second electrodes are disposed in parallel for each display line, and at the same time, a plurality of third electrodes electrically separated from the first and second electrodes. A method of driving a plasma display panel in which electrodes are arranged to intersect the first and second electrodes, and one frame is divided into X subfields in a plasma display panel in which discharge cells are formed at respective crossing regions. In one subfield of the X subfields, the N second electrodes are divided into L electrode blocks including a plurality of second electrodes (L is a natural number of 2 or more), and the first electrode block is included in the L electrode blocks. The plurality of first electrodes and the first electrode are applied by applying a relatively high voltage double-sided pulse to a common electrode commonly connected to the plurality of first electrodes corresponding to the plurality of second electrodes included. A first step of totally discharging discharge cells respectively formed at intersections of a plurality of second electrodes belonging to the block; Successively, scanning pulses of a predetermined voltage level are sequentially applied to a plurality of second electrodes belonging to the first electrode block, and scanning is performed, and corresponding to the discharge cells to be turned on among the discharge cells constituted by the plurality of second electrodes. Applying a data pulse to only the third electrode to discharge the address; A third step of continuously performing the first and second steps on each of the L-1 electrode blocks except for the first electrode block; And a fourth step of sustain discharge by alternately applying a discharge sustain voltage pulse between the N second electrodes and the L common electrodes commonly connected to the first electrode after the end of the third step.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. do.

The PDP driving method of the present invention will be briefly described as follows.

N scan electrode groups (Y ₁ , Y ₂ , ..., Y _N ) are divided into L (L is a natural number of 2 or more) scan electrode blocks including a plurality of scan electrodes, and each scan electrode block has a front surface in a reset section. The common sustain electrodes com1, com2,... Which continuously perform the discharge and the address discharge in the address section, and commonly connect the sustain electrodes corresponding to the plurality of scan electrodes included in each scan electrode block during front discharge of each scan electrode block. , comL), a relatively high voltage is applied to reduce the voltage level of the scanning pulse by using the active particles generated during full discharge during address discharge.

3 is a driving voltage waveform diagram according to an embodiment of the present invention applied to each electrode of the PDP. For convenience of description, four scan electrodes Y ₁ to Y ₄ and four sustain electrodes Y ₁ to Y are illustrated. Taking a PDP composed of ₄ ) as an example, it is a driving voltage waveform diagram in which four scan electrodes Y ₁ to Y ₄ are driven in two, that is, the first and second scan electrode blocks.

First, the common sustain electrode com1 is a common connection between sustain electrodes X ₁ and X ₂ respectively corresponding to two scan electrodes Y ₁ and Y ₂ included in the first scan electrode block. com2 is a common connection between the sustain electrodes X ₃ and X ₄ respectively corresponding to the two scan electrodes Y ₃ and Y ₄ included in the second scan electrode block.

As shown in FIG. 3, in the PDP driving method of the present invention, first, a relatively high voltage is applied to the common sustain electrode com1 to the sustain electrodes X ₁ and X ₂ and the first scan electrode block. By performing front discharge and spontaneous erasing for discharging the discharge cells respectively formed at the intersections of the scan electrodes Y ₁ and Y ₂ , the discharge cells are neutralized so that there is no problem in the continuous addressing operation. Subsequently, a scan pulse is applied to the scan electrodes Y ₁ and Y ₂ belonging to the first scan electrode block to perform scanning, and the data corresponding to the cells to be turned on among the cells constituted by the scan electrodes Y ₁ to Y ₂ . A data pulse is applied only to the electrode D to cause an address discharge between both electrodes. At this time, the active particles generated by the front discharge, that is, charged particles, excitation particles, etc. are used for address discharge of the scan electrode belonging to the first scan electrode block which is continuously performed so that the active particles are sufficiently present in the discharge cell. By performing the discharge, the scan pulses applied to the scan electrodes Y ₁ and Y ₂ belonging to the first scan electrode block during the address discharge are applied at a voltage level lower than that of the conventional voltage level.

Subsequently, a relatively high voltage is applied to the common sustaining electrode com2 to the intersection regions of the sustaining electrodes X ₃ and X ₄ and the scanning electrodes Y ₃ and Y ₄ belonging to the second scanning electrode block, respectively. By performing front discharge and spontaneous erasing to discharge the discharge cells to be formed, the discharge cells are neutralized so that there is no problem in the continuous addressing operation. In addition, a scan pulse is applied to the scan electrodes Y ₃ and Y ₄ belonging to the second scan electrode block to scan the data electrodes, and the data electrodes corresponding to the cells to be turned on among the cells configured by the scan electrodes Y ₃ to Y _{4 are} scanned. A data pulse is applied only to (D) to cause address discharge between both electrodes. At this time, the active particles generated by the front discharge, that is, charged particles, excitation particles, etc. are used for address discharge of the scan electrode belonging to the second scan electrode block which is continuously performed, so that the active particles are sufficiently present in the discharge cell. By performing the discharge, the scan pulses applied to the scan electrodes Y ₃ and Y ₄ belonging to the second scan electrode block during the address discharge are applied at a voltage level lower than that of the conventional voltage level.

When the address discharge of the scan electrodes is completed as described above, the sustain discharge is generated in the sustain section in the same manner as in the prior art so that an image is displayed in the cell turned on in the previous address section.

The PDP driving method of the present invention as described above reduces the voltage level of the scanning pulse applied during the address discharge as described above, but reduces the addressing time by performing the address discharge in a state where the active particles are sufficiently present in the discharge cell. In some cases, the pulse width of the scanning pulse may be reduced. Therefore, the address discharge is possible even with a small pulse width of the pulse pulse, so that the total scan time is reduced, and the number of addressable scan electrodes of each subfield can be increased with the reduced total scan time, thereby realizing a high definition PDP.

In addition, the PDP driving method of the present invention divides the N scan electrode groups Y ₁ , Y ₂ ,..., And Y _N into L scan electrode blocks including a plurality of scan electrodes to assist address discharge. Before performing the full addressing operation, the voltage level of the scan pulse is further increased as the active particles and the wall charges generated by the predetermined low voltage pulse applied to each scan electrode can be discharged in a state where it is more sufficiently present in the discharge cell. Can be lowered.

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.

According to the present invention made as described above, the N scan electrode groups Y ₁ , Y ₂ ,..., Y _N are divided into L (L is an integer of 2 or more) scan electrode blocks including a plurality of scan electrodes, and each scan is performed. By performing the front discharge in the reset section and the address discharge in the address section for each electrode block, scanning is applied to the scan electrode when address discharge is possible because address discharge is possible while active particles generated during the front discharge exist in the discharge cell. The voltage level of the pulse can be lowered, and the pulse width of the scanning pulse can also be reduced.

In addition, the present invention has an excellent effect of realizing a high-definition PDP by increasing the number of scan electrodes by reducing the pulse width of the scan pulse and reducing the total scan time.

Claims (2)

N (N is a natural number) first and second electrodes are disposed in parallel for each display line, and at the same time, a plurality of third electrodes electrically separated from the first and second electrodes may be arranged with the first and second electrodes. A plasma display panel driving method in which one frame is divided into X subfields in a plasma display panel arranged to cross each other, and discharge cells are formed in each crossing area, respectively. Dividing the N second electrodes into L (L is a natural number of two or more) electrode blocks including a plurality of second electrodes in any one of the X subfields, The plurality of first electrodes may be applied by applying a relatively high voltage back pulse to a common electrode commonly connected to the plurality of first electrodes corresponding to the plurality of second electrodes included in the first electrode block among the L electrode blocks. A first step of totally discharging discharge cells formed at intersections of the plurality of second electrodes belonging to the first electrode block; Successively, scanning pulses of a predetermined voltage level are sequentially applied to a plurality of second electrodes belonging to the first electrode block, and scanning is performed, and corresponding to the discharge cells to be turned on among the discharge cells constituted by the plurality of second electrodes. Applying a data pulse to only the third electrode to discharge the address; A third step of continuously performing the first and second steps on each of the L-1 electrode blocks except for the first electrode block; And A fourth step of sustain discharge by alternately applying a discharge sustain voltage pulse between the N second electrodes and the L common electrodes commonly connected to the first electrode after the end of the third step; Method of driving a plasma display panel comprising a. The method of claim 1, The first electrode is a sustain electrode, The second electrode is a scanning electrode, And the third electrode is a data electrode.