KR100490556B1 - Panel driving method and apparatus for representing gradation with address-sustain mixed interval - Google Patents

Abstract

The panel driving method according to the present invention for achieving the above technical problem is a method of dividing the cells provided with the scan electrode and the sustain electrode into a plurality of groups, addressing and sustaining discharge the cells belonging to each group, one frame period The display device is divided into a plurality of subfields, and the tone fields implemented by the subfields are differently assigned to selectively operate the subfields to determine the gray level of the visible luminance of the cell. The address period and the sustain period are sequentially performed on the cells of, but the address operation is performed on the cells of each group, and then the sustain period is performed on the cells of the addressed group. Perform an address operation on the cells of the cell, and perform the sustain period on the cells of any one group. The sustain period is selectively performed for other groups of cells that have already been previously addressed during the period, and in the subfield, the sustain period performed between the one address period and the next address period is the scan electrode. And a high level sustain pulse alternately applied to the sustain electrode, and the last high level sustain pulse is applied to the scan electrode among the high level sustain pulses alternately applied to the scan electrode and the sustain electrode.

Description

Panel driving method and apparatus for expressing gradation by mixing address period and maintenance period {Panel driving method and apparatus for representing gradation with address-sustain mixed interval}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for implementing gradation in a display device displaying an image by sequentially performing an address period and a sustain period as in a plasma display panel (PDP).

The electrode driving method of the PDP is disclosed in US Pat. No. 5,541,618. The panel driving timing can be divided into a reset (initialization) period, an address (write) period, and a sustain (display) period. The reset period initializes the state of each cell in order to perform the addressing operation smoothly on the cell, and the address period selects cells on the panel and cells not on the panel to accumulate wall charges. The sustain period performs a discharge for actually displaying an image in the addressed cells.

In the US patent, in order to implement gradation by the field-subfield structure, a method of driving the address period and the sustain period separately in time is adopted. In other words, the addressing operation from the first scan electrode to the last scan electrode is completed, and then the sustain operation is performed for all cells simultaneously. According to such a driving method, after the addressing operation is performed on one scan line, the sustain discharge operation is performed only after the addressing operation of the last scan line is completed. Therefore, in the case of implementing the gradation by the conventional method, there is a problem that a significant time gap occurs until the sustain discharge operation occurs in the cell where the addressing operation has occurred, the sustain discharge operation may become unstable.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a panel driving method and apparatus for smoothly maintaining discharge by minimizing a time gap between an address period and a sustain period in implementing gradation.

The panel driving method according to the present invention for achieving the above technical problem is a method of dividing the cells provided with the scan electrode and the sustain electrode into a plurality of groups, addressing and sustaining discharge the cells belonging to each group, one frame period The display device is divided into a plurality of subfields, and the tone fields implemented by the subfields are differently assigned to selectively operate the subfields to determine the gray level of the visible luminance of the cell. The address period and the sustain period are sequentially performed on the cells of, but the address operation is performed on the cells of each group, and then the sustain period is performed on the cells of the addressed group. Perform an address operation on the cells of the cell, and perform the sustain period on the cells of any one group. The sustain period is selectively performed for other groups of cells that have already been previously addressed during the period, and in the subfield, the sustain period performed between the one address period and the next address period is the scan electrode. And a high level sustain pulse alternately applied to the sustain electrode, and the last high level sustain pulse is applied to the scan electrode among the high level sustain pulses alternately applied to the scan electrode and the sustain electrode. The last high level sustain pulse may be applied to the sustain electrode among the high level sustain pulses alternately applied to the scan electrode and the sustain electrode in the last sustain period of the subfield. In the subfield, it is preferable that all cells of the panel are initialized before the address period of the first group is performed.

The panel driving apparatus according to the present invention for achieving the above technical problem is a panel driving apparatus for dividing the cells provided with the scan electrode and the sustain electrode into a plurality of groups and addressing and sustaining discharge cells of each group. A subfield processing unit for dividing a frame period into a plurality of subfields; A signal synthesizing unit for generating an address signal for selectively addressing cells to be turned on among cells of the panel to be applied for each subfield, and a sustain signal for sustaining discharge of the addressed cells; And a cell driver configured to drive the cells divided into a plurality of groups for each group while selectively operating the subfields according to the signal of the signal synthesizing unit, to determine the gradation of the visible luminance of the cell. The signal synthesizing unit sequentially performs an address period and a sustain period for cells belonging to each group, while cells of another group are in an idle state while performing an address period for cells of one group, and cells of one group. The address signal and the sustain signal are generated to selectively perform the sustain period for other groups of cells that have already been previously addressed, while performing the sustain period after performing the address period. The signal synthesizing unit alternately applies a high-level sustain pulse to the scan electrode and the sustain electrode in a sustain period performed between the one address period and the next address period in the subfield. Among the high level sustain pulses applied alternately to the sustain electrodes, the last high level sustain pulse generates a sustain signal to be applied to the scan electrodes. Here, in the last sustain period of the subfield, the last high level sustain pulse among the high level sustain pulses applied alternately to the scan electrode and the sustain electrode may be applied to the sustain electrode. In the subfield, all cells of the panel are preferably initialized before the address period of the first group is performed.

Hereinafter, the configuration and operation of a panel driving method and apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the embodiment of the present invention will be described with reference to the driving method of the AC plasma display panel.

1 is a partial perspective view of an AC plasma display panel to which the present invention may be applied. On the first glass substrate 100, a scan electrode 106 and a sustain (common) electrode 108 covered with the dielectric layer 102 and the passivation layer 104 are paired and arranged in parallel. A plurality of address electrodes 114 covered with the insulator layer 112 are provided on the second glass substrate 110. The address electrode 114 is arranged to be orthogonal to the scan electrode 106 and the sustain electrode 108. The partition wall 116 is formed on the insulator layer 112 between the address electrodes 114 in parallel with the address electrode 114. The phosphor 118 is formed on the surface of the insulator layer 112 and on both side surfaces of the partition wall 116. The first glass substrate 100 and the second glass substrate 110 are discharge spaces 120 formed by a plurality of scan electrodes 106, sustain electrodes 108, address electrodes 114, and barrier ribs 116. They are arranged to face each other with the gap between them. Discharge cells 122 are formed at each of the intersections between the address electrode 114 and the pair of scan electrodes 106 and sustain electrodes 108.

2 is an electrode arrangement diagram of a panel to which the present invention can be applied. The electrode has a matrix configuration of m × n. The address electrodes A1 to Am are arranged in the column direction, and the n scan electrodes SCN1 to SCNn and the sustain electrodes SUS1 to SUSn are arranged in the row direction. In FIG. 2, one discharge cell displayed at the intersection of the address electrode A ₂ , the scan electrode Y ₂ , and the sustain electrode X ₂ corresponds to the discharge cell 122 shown in FIG. 1. The discharge cells to be displayed are selected by the address electrodes and the scan electrodes, and sustain discharged by the scan electrodes and the sustain electrodes.

3 is a schematic block diagram of a panel driving apparatus according to an embodiment of the present invention. The analog video signal to be displayed on the panel 312 is converted into digital data and recorded in the frame memory 300. The subfield processing unit 302 divides digital data stored in the frame memory 300 as necessary and outputs the data in subfield units. For example, in order to display gray scales, a panel divides one frame of cell data stored in the frame memory 300 into a plurality of subfields, and outputs data of each subfield.

The signal synthesizing unit 306 generates a reset signal for generating a signal waveform to be applied to each electrode in the reset period, the address period, and the sustain period, in order to drive the address electrode, the scan electrode, and the sustain electrode forming the cells of the panel 312. A generator 306a, a write pulse generator 306b, and a sustain pulse generator 306c are provided. The reset signal generator 306a generates a reset signal for initializing the state of each cell, and the write pulse generator 306b generates an address signal for selecting and addressing a cell that is turned on and a cell that is not, and the sustain pulse generator 306c. Generates a sustain signal for discharging the cells addressed by the address signal. The signal generated by the signal synthesizing unit 306 is applied to the scan electrode Y driving unit 308 and the sustain electrode X driving unit 310 of the panel 312 at a predetermined timing.

The scan electrodes of the panel are divided into a plurality of groups, and the scan electrode driver 308 includes a plurality of drive circuits 308a, 308b, ... 308h for driving the scan electrodes of each group. The number of groups is changeable, and the number of driving circuits for driving the scan electrodes is determined according to the number of groups. On the other hand, the sustain electrode (X) driving unit 310 drives the sustain electrode of the panel 312. The timing controller 304 generates various timing signals necessary for the operations of the subfield processing unit 302 and the signal synthesizing unit 306.

The panel driving method of the present invention to be described below may be performed in the structure and the device shown in Figs.

FIG. 4 is a diagram illustrating a method of expressing gradation by using a plurality of subfields in one frame. One frame period forming one image is divided into a plurality of subfields, and different gray levels are assigned to each subfield. By selectively operating one or more subfields among the plurality of subfields, desired gray level can be achieved. The gray scale of the visible luminance is proportional to the number of sustain pulses applied to the cells in one frame period. By dividing one frame period corresponding to one screen into a plurality of subfields in time, assigning different sustain pulses to each subfield, and selectively operating the subfields, Gradation is determined by accumulation.

Referring to FIG. 4, one frame forming one image is usually divided into eight subfields to achieve 256 gray levels, and each subfield is sequentially divided into 1, 2, 4, 8, 16, 32, The number of different sustain pulses is allocated at the ratio of 64 and 128, and the sustain period of each subfield is allocated in proportion to the ratio. 4 illustrates an example in which one frame is divided into eight subfields in order to express 256 gray levels on the screen. In order to obtain luminance of 17 gray levels, cells may be addressed and sustained and discharged during the subfield 1 period and the subfield 5 period.

The gray level assigned to each subfield can be modified in various ways in consideration of gamma characteristics and panel characteristics. For example, in FIG. 4, the gray level assigned to the subfield 4 may be lowered from 8 to 6, and the gray level assigned to the subfield 6 may be increased from 32 to 34. FIG. In addition, the number of subfields forming one frame can be variously modified according to design specifications.

In order to implement the driving method according to the present invention, cells constituting the panel are divided into a plurality of groups, and operations are controlled for each group. In the case of an AC PDP, the scan electrodes are divided into a plurality of groups in a predetermined manner. Referring to FIG. 4, an example in which the scan electrodes are divided into n groups G1 to Gn is shown.

FIG. 5 is a schematic conceptual view illustrating a preferred embodiment of a panel driving method using an address / dielectric field mixing method, which is a basic concept of the present invention. One frame period is divided into a plurality of subfields, for example, eight subfields as shown in FIG. 4, and a gray level implemented by each subfield is allocated differently. FIG. 5 illustrates a panel driving method for dividing cells of a panel into a plurality of groups, and addressing and sustaining discharge of cells belonging to each group in one subfield.

The scan electrodes of the panel are divided into a plurality of groups G1 to Gn to sequentially perform address operations on the scan electrodes of each group. After the address operation is performed for one group, a sustain discharge pulse is applied to the scan electrodes of the group to perform the sustain period. If the sustain period is performed for one group of scan electrodes, the sustain period can be selectively performed for the other group of scan electrodes that have already been addressed. In this manner, a sustain period of a certain period is performed following the address period for one group of cells, and then an address period is performed for the scan electrodes of another group in which the address operation has not yet been performed. Here, the number of scan electrodes belonging to each group may be equally divided or arbitrarily adjusted for each group while dividing the scan electrodes constituting the panel into a plurality of groups.

In FIG. 5, one subfield may be displayed by being divided into a reset period R, a write / sustain mixed period T1, a common sustain period T2, and a luminance correction period T3. In the figure, the block indicated by the dot is the writing (address) period of the mixing section T1, the section indicated by the left diagonal line is the holding period of the mixing section T1, and the section indicated by the left and right diagonal lines is the common section T2. The maintenance period of and the section indicated by the right diagonal line indicate the maintenance period of the correction section T3, respectively.

Here, the common sustain period T2 and the luminance correction period T3 may or may not be applied depending on the subfields. Whether this is applied depends on the specification of the gradation diagram assigned to the subfield. In the case of the subfield assigned to the low gradation, the maintenance period for implementing the gradation is relatively short, and in the case of the subfield having the high gradation, the required maintenance period should be relatively long. Therefore, the low gradation assigned subfield may be composed of only the write / maintain mixed section T1, and the assigned high gradation subfield may include the write / maintain mixed section T1 and the common maintenance section T2. And it may be configured to include both the luminance correction section (T3). On the other hand, the subfield to which the intermediate degree of gradation is allocated may also be composed of the write / sustain mixing section T1 and the luminance correction section T3 without the common holding section T2.

The reset period R initializes the wall charge state of the cell by applying reset pulses to the scan lines of all groups. A reset period R is performed before entering the addressing process, which is carried out over the entire screen, thus creating a fairly even and evenly distributed wall charge arrangement. By one reset period R performed before the write / sustain mixing section T1 of each subfield, the wall charge conditions in all cells are similarly formed.

The write / sustain mixing section T1 will be described. In the first group G1, the scan pulse is sequentially applied from the first scan electrode Y ₁₁ to the last scan line Y _1n to perform the address period AG1. When all the address operations for the cells of the first group are completed, the sustain period S11 is performed to sustain and discharge these addressed cells by a certain number of sustain pulses.

When the first holding period S11 of the first group ends, the address period AG2 for the cells of the second group is performed. It is preferable that a separate operation pulse is not applied to the cells of the other groups during the address period AG2 of the second group. However, within the address period AG2 of the second group, it is possible to apply the sustain pulse to the electrodes of the other group for a time after the scan pulse is applied to one scan electrode and before the scan pulse is applied to the next scan electrode. This is also applicable to the case of other group address periods.

When the address period AG2 of the second group ends, that is, when all the addressing operations for the scan electrodes belonging to the second group are completed, the first holding period S21 for the second group is performed. At this time, the second holding period S12 is also performed in the first group in which the address period has already been performed. However, if the gray level is satisfied by the first holding period S11 of the first group, the second holding period S12 of the first group may not be performed. Of course, the cells for which the address period has not yet been performed remain idle.

When the first holding period S21 of the second group ends, the address period SG3 and the first holding period S31 are performed in the same manner as described above for the third group, and the first holding period of the third group is performed. During the period S31, the sustain periods S13 and S22 may also be performed for the cells of the first and second groups in which the address period has already been performed. However, if the gradation level is satisfied by the first and second sustain periods S11 and S21 of the first and second groups, additional maintenance periods S13 and S22 may not be performed.

After the above process, the scan pulses are sequentially applied to the scan electrodes belonging to the last group Gn to perform the address period AGn and then the sustain period Sn1. While the sustain period Sn1 is performed, the sustain period is also performed for the cells of other groups.

FIG. 5 illustrates an example in which all of the cells in the group in which the address period was previously performed are performed while the sustain period is performed in one group of cells. If it is assumed that the number of sustain pulses applied during the unit sustain period is the same, and thus the luminance expressed by the same is the same, the cells of the first group will exhibit n times the luminance as compared to the cells of the nth group. Similarly, compared to the cells of the n-th group, the cells of the second group will exhibit n-1 times the luminance, and the cells of the Gn-1 group will exhibit the twice the luminance. In order to equally correct the luminance difference for each group, a predetermined additional holding period is required, which is the luminance correction period T2 shown in FIG. 5.

The luminance correction section T3 is a sustain discharge section that is selectively performed for each group so that the gradations of the cells of each group are equally corrected with each other.

The common maintenance period T2 is a period in which sustain pulses are commonly applied to all the cells simultaneously for a predetermined period of time, and is assigned to each subfield by the mixing period T1 or the mixing period T1 and the correction period T2. The assigned gradation can also be selectively performed when the specification is not satisfied. As shown in FIG. 5, the common holding section T2 may be performed after the mixing section T1 or may be performed after the luminance correction section T3.

Here, the common sustain period T2 and the luminance correction period T3 may or may not be applied depending on the subfields. Whether this is applied depends on the specification of the gradation diagram assigned to the subfield. In the case of the subfield assigned to the low gradation, the maintenance period for implementing the gradation is relatively short, and in the case of the subfield having the high gradation, the required maintenance period should be relatively long. Therefore, the low gradation assigned subfield may be composed of only the write / maintain mixed section T1, and the assigned high gradation subfield may include the write / maintain mixed section T1 and the common maintenance section T2. And it may be configured to include both the luminance correction section (T3). On the other hand, the subfield to which the intermediate degree of gradation is allocated may also be composed of the write / sustain mixing section T1 and the luminance correction section T3 without the common holding section T2.

The example shown in FIG. 5 is an embodiment in the case where the gradation degree assigned to the subfield is high. Since the length of the sustain period is different for each group in the mixing section T1, the luminance of all cells is the same. For each group, additional maintenance periods are performed. For example, the luminance of the cells of the first group G1 is determined by the sum of the sustain periods S11, S12,... S1n and the common sustain period T2 performed during the mixing period T1. The cells of the group have the highest luminance at the time when the correction section T3 starts. In order to ensure that the cells of the other group also have the luminance of the cells of the first group, an additional holding period S2n is applied to the cells of the second group G2 (this period is substantially the first holding period of the first group). (Corresponding to S11), and additional sustain periods S3 and n− corresponding to the first and second sustain periods S11 and S12 of the first group for the cells of the third group G3. 1, S3, n). In this manner, additional sustain periods Sn 2, Sn 3, ,,, Sn, n must be performed for the cells of the last group Gn. By doing so, all the cells of the panel can exhibit the same brightness.

As described above, when the sustain period for all cells ends, the operation of one subfield is completed and the reset period of the next subfield starts again.

Meanwhile, in FIG. 5, only the reset section R and the write / maintain mixed section T1 are noted, and the sustain discharge section is represented by the letter S, where R → AG1 → S → AG2 → S → AG3 → S → ... → S → AGn → S, and after one reset period R, the address sections AG1, AG2, AG3, ..., AGn of each group are sequentially performed. In this case, the further the distance from the reset section R, i.e., toward the AGn side, increases the probability that an error occurs in the address operation. This is because the wall charge conditions in all the cells are similarly formed by the reset period R performed simultaneously before entering the address process. While the address operation and the sustain discharge operation are alternately performed, the walls of the group not yet addressed are performed. This is due to the deterioration of the charge state.

FIG. 6 illustrates a preferred embodiment in which the hybrid panel driving method shown in FIG. 5 is applied to an AC PDP. For convenience of description, the scan electrodes are divided into two groups G1 and G2 and performed between addressing sections for each group. It is a timing chart for explaining the sustain discharge period S.

First, in the reset section R, reset pulses are alternately applied to the sustain electrodes X and the scan electrodes Y ₁₁ ,..., Y 1 _n , Y ₂₁ ,... Y _{2 n} to erase sustain discharges. And an address condition is formed.

Next, the addressing period AG1 of the first group G1 is performed. At this time, the AG1 is applied with the bias voltage Ve to the sustain electrode X, and simultaneously turns on the scan electrodes Y ₁₁ to Y _1n and the address electrodes which form the cells to be displayed in the first group G1. Select the display cell. After the addressing period AG1 of the first group G1 is performed, the sustain pulses V _S are alternately applied to the sustain electrodes and the scan electrodes, so that the sustain discharge S of the first group G1 is performed. . After the sustain discharge S of the first group G1 is performed, the addressing period AG2 of the second group G2 is performed. The case where n scan electrodes Y ₂₁ to Y _2n belong to the second group G2 is illustrated. After AG2 is performed, sustain pulses are alternately applied to the sustain electrode and the scan electrode, and sustain discharge S of the first group G1 and the second group G2 is performed. The wall charge state formed at the same time on the full screen for addressing by the reset section R differs between the first group addressing AG1 and the second group addressing AG2, and in particular, the second group addressing AG2. The lower the wall charge margin, the higher the probability of an addressing error.

In particular, in FIG. 6, when the last sustain pulse S _XL of the sustain discharge period S after the address section AG1 of the first group G1 is applied to the sustain electrode X is applied to the sustain electrode X, Scanning electrodes Y _{21 ˜} Y _{2 n} wall charge state is further disturbed. This will be described as follows with reference to FIGS. 7 and 8.

FIG. 7 illustrates a state in which the wall charge state of the scan electrodes Y _{21 to} Y _{2 n} of the second group G2 is disturbed by the last sustain pulse S _XL applied to the sustain electrode X. Timing diagram. As indicated by arrow 7, it is at a high level (V _S) of the electrode current from the low level (V _G) electrode to flow. Therefore, when the last high level sustain pulse S _XL is applied to the sustain electrode X, the wall charges formed as negative charges on the scan electrodes Y _{21 to} Y _{2 n} of the second group by the initial reset period R. The state is disturbed.

FIG. 8 is a view for explaining the case of FIG. 7 in the electrode structure, and the Y ₂₁ electrode of the second group before the address section AG2 is performed by the last high level sustain pulse SXL applied to the sustain electrode X; This is what is affected. Here, reference numeral A denotes an address electrode and reference numeral BR denotes a partition wall. As such, if the last high level sustain pulse S _XL is applied to the sustain electrode X, positive charges are emitted from the sustain electrode X. FIG. The positive charge generated at the sustain electrode paired with the scan electrode Y _1n of the first group G1 disturbs the wall charge state formed with the negative charge on the first scan electrode Y ₂₁ of the adjacent second group G1. Done. In this case, the disturbed scan electrode Y ₂₁ of the second group G2 fails to perform a proper function during the address operation and increases the probability that an error occurs.

6 to 8, the disturbance of the wall charge state before performing the address interval can be compensated by applying the last sustain pulse of the sustain discharge of the subfield to the scan electrode. Explain together.

Of the desired sustain discharge embodiment of the present invention, the scan electrode (Y) and the sustain electrodes maintain the last high level from the high level (V _S) sustain pulses are alternately applied to the (X) pulses (S _YL) shown in Figure 9 And scanning electrodes Y ₁₁ to Y _1n and Y ₂₁ to Y _2n . At the end of the sustain period S, when the last high level sustain pulse S _YL is applied to the scan electrode, the negative ions emitted from the sustain electrode X move to the high level scan electrode. Therefore, the scan electrode can stably maintain the wall charge state formed by the negative charge, and can perform the stable address discharge by making the wall charge state favorable to the address discharge.

FIG. 10 is a modified embodiment of FIG. 9, in which the last sustain pulse S _XL is applied to the sustain electrode X in the last sustain discharge period after the address period AG2 of the second group G2. This is because after the last sustain discharge period, the cell initialization is performed by the reset section R of the next subfield, and thus the last sustain pulse application order may be don't care.

3, the configuration and operation of the apparatus implementing the panel driving method as described above will be described. Referring to FIG. 3, the address operation and the sustain operation according to the driving method according to the present invention are performed by the signal synthesizing unit 306, the scan electrode Y driving unit 308, and the sustain electrode X driving unit 310. Performed for cells of 312.

The panel driving apparatus according to the present invention divides the cells of the panel 312 into a plurality of groups, addresses and sustains and discharges cells belonging to each group, and the signal synthesizing unit 306 maintains an address period and maintenance for the cells belonging to each group. Periodically, the cells of another group are in a dormant state while performing an address period for one group of cells, and while the sustain period is performed after performing an address period for one group of cells. The address signal and the sustain signal are generated to selectively perform the sustain period for the other groups of cells in which the address period was previously performed.

In response to the address signal, the scan electrode Y driver 308 applies a scan pulse to the scan electrodes for each group (in this case, an address pulse is applied to the address electrode) to perform an address period. At this time, the sustain electrode (X) driver, in response to the address signal, while applying a different bias voltage for each addressing group while sequentially addressing each group, to compensate for the decrease in the margin of the wall charge. After addressing is performed for each group, the scan electrode X driver 308 and the sustain electrode X driver 310 alternately hold sustain pulses to the scan electrodes and sustain electrodes of each group in response to the sustain signal. The maintenance period is performed by authorizing.

The signal synthesizing unit 306 performs all the address periods for the cells belonging to all groups according to the gradation degree assigned to each subfield, and then performs the sustain period in common for a certain period for the cells belonging to all the groups. A common maintenance section may be performed by further generating a sustain signal. In addition, the luminance correction period may be performed by further generating a sustain signal for selectively performing an additional sustain period for the cells of each group so that the cells of each group satisfy the predetermined gray level. In addition, the signal synthesizing unit 306 scans the last high level sustain pulse from among the high level sustain pulses applied alternately to the scan electrode Y and the sustain electrode X in order to perform the sustain discharge method described with reference to FIG. 9. It may be implemented to be applied to the electrode (Y).

The present invention is applicable to a display device that sequentially performs an address period for preselecting a cell to be turned on and a sustain period for emitting the selected cell in a method of driving an electrode of a panel. For example, not only an AC type PDP but also a DC type PDP, an apparatus for displaying a screen by sequentially performing an address period and a sustain period by space charge, such as an EL (optical) display device or a liquid crystal device, may be used. It will be apparent to those skilled in the art that the technical idea may be applied as it is.

The invention can also be embodied as computer readable code on a computer readable recording medium. Computer-readable recording media include any type of recording device that stores programs or data that can be read by a computer system. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, hard disk, floppy disk, flash memory, optical data storage, and the like. Here, the program stored in the recording medium refers to a series of instruction instructions used directly or indirectly in an apparatus having an information processing capability such as a computer to obtain a specific result. Thus, the term computer is used to mean all devices having an information processing capability for performing a specific function by a program, including a memory, an input / output device, and an arithmetic device, regardless of the name actually used. In the case of a device for driving a panel, its use is limited to a specific field of panel driving, and in reality, it is a kind of computer.

As described above, the signal synthesizing unit 306 included in the panel driver includes an integrated circuit including a memory and a processor therein to store a program in which a method for driving the panel is implemented. In driving the panel, a program stored in a memory may be executed to perform the addressing and holding operation according to the present invention. Therefore, the integrated circuit in which the program for executing the panel driving method is stored should be interpreted as a kind of the recording medium.

In particular, a method for driving a panel is written by a schematic or ultra-high-speed integrated circuit hardware description language (VHDL) or the like on a computer, and is connected to a computer by a programmable integrated circuit such as a field programmable gate array (FPGA). Can be implemented. The recording medium includes such a programmable integrated circuit.

The best embodiments have been disclosed in the drawings and specification above. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the panel driving method and apparatus of the address / dielectric field mixing method according to the present invention have the following effects.

First, the panel driving method according to the present invention expresses the gradation in a frame-subfield method, so that the cells of the panel are divided into a plurality of groups, and the address period and the sustain period are continuously performed in each group during each subfield period. do. Therefore, since the sustain discharge operation occurs within a short time after the address operation in each cell, stable sustain discharge can be obtained even if the width of the scan pulse and the address pulse applied in the address period is narrower. As a result, the time required for addressing the entire cell is reduced, which means that more time can be allocated to the sustain discharge during one TV field time. Therefore, the brightness of the screen can be improved, and a high gradation device can be realized even for a panel having more scan lines. In addition, the present invention provides flexibility to drive each subfield in the most suitable manner according to the gradation degree assigned to each subfield.

In performing the mixed panel driving method, the last high level sustain pulse is applied to the scan electrode in the sustain discharge section performed between the address section and the address section of each group in one subfield. This prevents the wall charge state of the scan electrodes formed of negative charges from being disturbed by one reset operation. Therefore, the wall charge state of the scan electrode can be stably maintained, and the wall charge state advantageous for the address discharge can be made to perform stable address discharge.

The invention is not limited to the examples described above and represented in the drawings. Those skilled in the art taught by the above-described embodiments, many modifications to the above-described embodiments are possible by substitution, erasure, merging, etc. within the scope and object of the present invention described in the following claims.

1 is a partial perspective view of an AC plasma display panel to which the present invention may be applied.

2 is an electrode arrangement diagram of a panel to which the present invention can be applied.

3 is a view showing an embodiment of a panel driving apparatus according to the present invention.

FIG. 4 is a diagram illustrating a method of expressing gradation by using a plurality of subfields in one frame.

FIG. 5 is a schematic conceptual view of a panel driving method using an address / oil aliphatic mixing method according to an exemplary embodiment of the present invention.

FIG. 6 is a timing diagram illustrating an exemplary embodiment in which the hybrid panel driving method shown in FIG. 5 is applied to an AC type PDP.

FIG. 7 is a timing diagram illustrating a state in which wall charge states of the scan electrodes of the second group are disturbed by the last sustain pulse applied to the sustain electrodes.

FIG. 8 is a view for explaining the case of FIG. 7 in the electrode structure.

9 is a timing diagram for explaining a preferred embodiment of the panel driving method for preventing the wall charge states of the scan electrodes of the second group from being disturbed.

10 is a timing diagram for explaining another preferred embodiment of the panel driving method for preventing the wall charge states of the scan electrodes of the second group from being disturbed.

Claims (7)

In the method for dividing the cells provided with the scan electrode and the sustain electrode into a plurality of groups and addressing and sustain discharge the cells belonging to each group, One frame period is divided into a plurality of subfields, and the gradations implemented by the subfields are differently assigned to selectively operate the subfields to determine the gradation of the visible luminance of the cell. At least one subfield sequentially performs an address period and a sustain period for the cells of each group, performs an address operation on the cells of each group, and then performs the sustain period for the cells of the addressed group. After the sustain period ends, the address operation is performed on the cells of the other group to selectively perform the sustain period on the cells of the other group that have already performed the address period while the sustain period is performed on the cells of one group. , And In the subfield, the sustain period performed between the one address period and the next address period is performed by alternately applying a high level sustain pulse to the scan electrode and the sustain electrode, And among the high level sustain pulses applied alternately to the scan electrode and the sustain electrode, the last high level sustain pulse is applied to the scan electrode. The method of claim 1, And a last high level sustain pulse is applied to the sustain electrode among the high level sustain pulses alternately applied to the scan electrode and the sustain electrode in the last sustain period of the subfield. The method of claim 1, wherein the subfield is And all the cells of the panel are initialized before the address period of the first group is performed. In the panel driving apparatus for dividing the cells provided with the scan electrode and the sustain electrode into a plurality of groups, addressing and sustain discharge the cells belonging to each group, A subfield processing unit that divides one frame period into a plurality of subfields; A signal synthesizing unit for generating an address signal for selectively addressing cells to be turned on among cells of the panel to be applied for each subfield, and a sustain signal for sustaining discharge of the addressed cells; And According to the signal of the signal synthesizing unit, while driving the cells divided into a plurality of groups by selectively operating the sub-fields, and includes a cell driver for determining the gradation of the visible luminance of the cell, The signal synthesis unit, The address period and the sustain period are sequentially performed for the cells belonging to each group, while the cells of the other group are in the dormant state while the address period is performed for the cells of one group, and the address period for the cells of one group. During the sustain period after the operation, the address signal and the sustain signal are generated to selectively perform the sustain period for the cells of other groups that have already been previously addressed. The signal synthesis unit, In the subfield, a sustain pulse of a high level is alternately applied to the scan electrode and the sustain electrode in a sustain period performed between the one address period and the next address period, and to the scan electrode and the sustain electrode. And a sustain signal is generated such that the last high level sustain pulse is applied to the scan electrode among alternating high level sustain pulses. The method of claim 4, wherein And a last high level sustain pulse is applied to the sustain electrode among the high level sustain pulses alternately applied to the scan electrode and the sustain electrode in the last sustain period of the subfield. The method of claim 4, wherein the subfield is And all the cells of the panel are initialized before the address period of the first group is performed. A computer-readable recording medium having recorded thereon a program for executing the method of claim 1 on a computer.