KR20060014077A - Driving method for plasma display panel - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of driving an AC type plasma display panel (PDP), which is advantageous for high speed driving due to a small variation between scan lines and is stable, and does not concentrate power consumption at a specific time. The present invention relates to a novel driving method which is easy to design, prevents degradation of phosphors and image quality deterioration due to an increase in panel temperature, and is advantageous for low gradation expression power and pseudo contour noise reduction. In the driving method of the plasma display panel of the present invention, one frame of image information is divided into one or more subfields for implementing gray scale by combination, and each subfield is divided into one or more driving units (T), and the driving unit Each of (T) includes a writing period, a sustaining period, and an erasing period separated in time, and writing data for the corresponding subfield during the writing period of the first of the driving units T constituting the subfield. ; And erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield.

Plasma Display, PDP, Driving Method, ADS, AWD, Driving Waveform

Description

Driving method of plasma display panel {DRIVING METHOD FOR PLASMA DISPLAY PANEL}

1 is a perspective view illustrating the structure of an AC plasma display panel (PDP) applied to the present invention.

2 is an illustration of a time division diagram of a prior art ADS driving scheme.

3A and 3B show an operation during one subfield in detail in the ADS driving method.

4 is an illustration of a time division diagram of the AWD driving scheme of the prior art.

5 is an illustration of a time division diagram in one embodiment of a drive scheme of the present invention.

6 is a diagram illustrating a configuration of a basic driving unit T and an arrangement of subfields in the time division diagram of FIG. 5.

7 is a diagram illustrating an arrangement of driving waveforms in an embodiment of the present invention.

FIG. 8 is an enlarged example of the basic driving unit T of the driving waveform shown in FIG. 7.

9 is a diagram illustrating an embodiment of a driving waveform for improving low gray scale expressive power according to another embodiment of the present invention.

FIG. 10 is an enlarged example of the basic driving unit T of the driving waveform illustrated in FIG. 9.

11 is a view for explaining the principle of erasing multiple narrow pulses as an example of an erase waveform used in the driving method of the present invention.

FIG. 12 illustrates an example in which the arrangement of subfields is changed for each scan line as an example for reducing the pseudo pseudo contour noise of the present invention.

FIG. 13 (a) shows the operating range of the driving voltage obtained when the driving waveform of the present invention is applied to a conventional panel, and FIG. 13 (b) has a fluorescent film coated with magnesium oxide of the driving waveform of the present invention. The operating range of the driving voltage obtained when applied to the panel is shown.

14 is another embodiment of an erase waveform applicable to the driving method of the present invention.

FIG. 15 illustrates a configuration of a basic driving unit T when the erase waveform of FIG. 14 is applied.

FIG. 16 is a diagram illustrating another embodiment of a driving waveform of the present invention for improving low gradation power.

17 shows an example of a basic driving unit configuration when the number of subfields is m and the number of scan lines exceeds 2 ^m −1.

18 and 19 show another example of the erase waveform applicable to the driving method of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: top plate 8: top dielectric layer

2: lower plate 9: protective layer

3: bulkhead 4: fluorescent film

5: lower dielectric layer Y: scan electrode

X: discharge sustain electrode A: address electrode

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of driving an alternating current (AC) type plasma display panel (PDP). More particularly, the high speed driving of the conventional ADS (Address Display period separated) driving method is difficult. Concentration of power consumption and panel temperature rise due to the concentration of point and sustain discharge times, and the complexity of the driving circuit and the initialization period, which are not solved by the address while display (AWD) driving method proposed as an alternative, It is an object of the present invention to provide a method of driving a new AC plasma display panel which can overcome problems such as lowering of contrast ratio due to discharge.

1 is a perspective view showing a panel structure of an AC PDP. As shown, the panel of the AC type PDP comprises: a plurality of scan electrodes Y and a discharge sustaining electrode X disposed in parallel with each other on the plate glass, a top dielectric layer 8 covering thereon, and a protective layer formed thereon It has the top board 1 containing (9). In addition, the panel may include: an address electrode A formed in a direction perpendicular to the scan electrode Y and the discharge sustain electrode X, and a lower plate dielectric layer 5 covering the address electrode A to form a reflective layer. The lower plate 2 on which the partition wall 3 for separating each cell and the address electrode A is placed in parallel and applied to the side and bottom surfaces of the partition wall 3 to emit visible light is formed. Have After evacuating between the upper plate 1 and the lower plate 2, the discharge space between the upper plate 1 and the lower plate 2 is filled with a binary or ternary inert gas containing xenon (Xe) gas, One discharge cell is formed at a portion where the scan electrode Y of the upper plate 1, the discharge sustain electrode X, and the address electrode A of the lower plate 2 cross each other, and for color image display. Three cells, red, green, and blue, combine to form a pixel.

In order to drive such an AC plasma display panel, conventionally, an address display separation driving method (ADS: Address Display Period Separated (see Korean Patent No. 88852 or US Patent No. 5,541,618) schematically shown in FIG. 2) is most widely used. Has been. In the ADS driving method, eight subfields having different brightnesses are provided for one TV field (= 16.7 ms) representing an image for 256-gradation representation as shown in FIG. 2, and each subfield is again initialized period and address period. (Or writing period) and discharge sustain period. That is, each of the subfields has a length of discharge sustaining periods corresponding to 2 ⁰ , 2 ¹ , 2 ² , 2 ³ , 2 ⁴ , 2 ⁵ , 2 ⁶ , 2 ⁷ , and a combination of these subfields. 256 (= 2 ⁸ ) gray scales can be expressed. As shown in FIG. 2, in the ADS driving method, the initialization period 100, the address period 200, and the discharge sustain period 300 proceed simultaneously for all the scan lines on the panel.

3A and 3B show an operation during one subfield in detail in the ADS driving method. First, the initialization period 100 is a process of equalizing the wall charge states of all cells, and in addition to deleting information of the previous image, the initial conditions of all cells are made the same so that subsequent address discharges can occur under the same initial conditions. It plays a role. In the address period 200, in order to display an image according to the video signal, in the subsequent discharge sustain period 300, scan electrodes Y orthogonal to each other in each of the cells to make selections for cells to be turned on and cells to be turned off. ) To form a positive wall charge on the scan electrode (Y), and to form a negative wall charge on the address electrode (A), respectively. In this case, a discharge sustain voltage lower than the discharge start voltage is applied between the scan electrode Y and the discharge sustain electrode X so that sustain discharge is sustained only for the cells that are turned on in the address period. Through the discharge between Y) and the address electrode A, only the cells in which the wall charges are formed are sustained.

In this ADS driving process, since the address period is completely separated from the discharge sustain period over all the scan electrodes, the time at which the address occurs after initialization and the time to transfer to the sustain discharge after address are different for each scan electrode. That is, when writing (address) of the scan electrode corresponding to the last line of the panel is made, since a relatively long time passes after the initialization period ends, it is considerably different from the condition that the scan electrode corresponding to the first line is written. Under other conditions, address discharge is caused. Therefore, the dispersion of the write discharge characteristics is large for each scan electrode, which is not suitable for high-speed driving, and similarly, the time to move from the write discharge to the sustain discharge is not uniform for each scan electrode, so that the first sustain discharge does not occur uniformly. There is this.

In addition, since all the cells simultaneously perform the sustain discharge, the power consumption is concentrated at a certain time, so that the design of the power circuit requires a large instantaneous power consumption, and it is difficult to design the panel. It may also lead to an increase in temperature, resulting in deterioration of image quality such as phosphor degradation and afterimage.

As a conventional technique proposed to solve such a problem, a so-called AWD (Address While Display) driving method in which an address period and a discharge sustain period are mixed with each other has been proposed as shown in FIG. If the method is applied as it is, the driving circuit is complicated, the background light is increased due to the strong discharge during the initialization period, and the deterioration in image quality due to the lowering of the contrast ratio is not applied to the actual product.

The present invention is to solve the above problems, and unlike the conventional driving method of the PDP, the desired gradation is a combination of the basic driving unit (T) consisting only of the writing period, the discharge sustain period and the erase period without an initialization period. The present invention proposes a driving method for improving the contrast reduction due to the background light, which is one of the problems of the conventional driving method.

In the present invention, one TV field is divided into a plurality of basic driving units T (for example, 255 as shown in FIG. 5), and the set of one or more driving units forms one subfield. In addition, the basic driving units T belonging to the same subfield and corresponding to each other in the order are present at different times in each scan electrode (for example, sequentially in each scan line as shown in FIG. 5). Each subfield is arranged so that the time points at which writing (addressing) of the corresponding subfield occurs for each scan electrode are different (for example, as shown in FIG. 6). It is made to exist during sustain discharge period. Through this, the present invention is to improve the phosphor degradation and afterimage characteristics due to the instantaneous power consumption increase and panel temperature rise due to the concentration of the sustain discharge at a specific time, as in the conventional ADS driving method.

In addition, unlike the conventional ADS driving method, the writing period is shortened by setting the basic driving unit T, thereby reducing the difference between scan electrodes of the time interval from the erasing operation until the writing occurs, thereby increasing the driving speed. This facilitates and also shortens the time from the write discharge to the sustain discharge so that the transition to the sustain discharge can be made stable.

Furthermore, in the driving method of the present invention, unlike the ADS driving method, the configuration order of the subfields can be arbitrarily changed for each scan line, thereby eliminating "motion picture pseudo contour noise" which has been pointed out as a problem in the existing moving picture representation. Take advantage.

In the present invention, since the subfield can be added only by adding the basic driving unit T, a subfield having a weight less than 1 bit (for example, 0.5 bit) can be implemented to improve low gray scale expression power. It will be easy to obtain a high quality image.

In addition, in the conventional AWD driving method, there is a problem in that the driving circuit is very complicated due to different driving waveforms for each line, but in the present invention, the same driving waveform can be used for each scan electrode or sustain electrode (for example, FIG. 7). As shown in FIG. 2, the driving circuit can be configured with a simple circuit.

According to an aspect of the present invention, there is provided a method of driving a plasma display panel including a plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, and a plurality of orthogonal to the scan electrodes. A method of driving an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel having an address electrode and a plurality of discharge cells formed at respective points perpendicular to the scan electrode and the address electrode, One frame of the image information is divided into one or more subfields for implementing gradation by combination, each of the subfields is divided into one or more driving units (T), and each of the driving units (T) is temporally A divided write period, a sustain period, and an erase period, wherein the sub Writing data for the corresponding subfield during the writing period of the first of the driving units (T) constituting the field; And erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield.

According to another aspect of the present invention, there is provided a method of driving a plasma display, wherein one frame of image information is divided into one or more driving units (T), and each of the driving units (T) has a writing period and a sustaining period separated in time. And an erase period, wherein a predetermined waveform for generating an erase discharge is applied to the scan electrode in the erase period, and a waveform applied to the scan electrode for the erase discharge corresponds to a section in which a plurality of narrow pulses are repeated. It is characterized by having a waveform having one or more.

According to another aspect of the present invention, in order to display predetermined image information on an AC plasma display panel, a plasma display apparatus divides one frame of the image information into one or more subfields to implement gradation by combining. Each of the subfields is divided into one or more driving units T, and each of the driving units T includes a writing period, a sustaining period, and an erasing period separated in time, and constitutes the subfield. Driving means for writing data for the corresponding subfield during the writing period of the first of (T); And driving means for erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield.

Preferably, in each of the above scan electrodes, the start time of one subfield of one scan electrode is different from the start time of the same subfield in another adjacent scan electrode.

Here, in the n th scan electrode of the panel, the start time of the m th subfield may have a time difference of one driving unit (T) from the start time of the m th subfield in the n + 1 th scan electrode. have.

Preferably, the writing period in the driving unit T is a period equal to or more than a time obtained by multiplying the pulse width of a unit address pulse by at least the total number of the subfields, and alternately between the scan electrode and the sustain electrode during the sustain period. The sustain pulse is applied, and in the erase period, a predetermined waveform for generating erase discharge is applied to the scan electrode.

In addition, the waveform applied to the scan electrode for the erase discharge is preferably a waveform having one or more sections in which a plurality of narrow pulses are repeated.

Here, the width of each narrow pulse is preferably 300ns or less.

In addition, the waveform applied to the scan electrode for the erase discharge may be inserted into a section in which a pulse having a negative polarity is applied between sections in which a plurality of narrow pulses are repeated.

If necessary, the plurality of narrow erase pulses may be applied to overlap the ramp waveform that increases with time.

In addition, if necessary, the sustain period of the driving unit T constituting the subfield is divided so as to implement low gradation that is less than that which can be implemented as a subfield having a minimum time length among the subfields. In addition, one or more second writing periods may be inserted therebetween.

If necessary, noises due to the moving picture pseudo contour may be removed by changing the arrangement order of the subfields constituting the one frame according to the scan line.

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

The present invention relates to a display panel for a TV or monitor of VGA (typically 480 horizontal lines), XGA (typically 768 horizontal lines), HD (typically 1080 horizontal lines), or other specially designed small, medium or large display panels. In various cases, the present invention may be modified and applied according to the specific specification and the number of gray scales to be implemented. Hereinafter, in order to understand the technical spirit of the present invention, a case of implementing 256 gray scales will be exemplarily described with reference to the embodiment to which the present invention is applied.

FIG. 5 illustrates an example in which one TV field is divided into driving units T in order to implement 256 gray levels in a VGA panel having 480 scan lines. In order to implement 256 gray scales, a combination of eight subfields each having a length of emission intervals corresponding to 2 ⁰ , 2 ¹ , 2 ² , 2 ³ , 2 ⁴ , 2 ⁵ , 2 ⁶ , and 2 ⁷ Gradation is implemented, and at this time, 8 bits of image data are required. However, since it is possible to implement 2 ⁿ gradations using general n bits of data, the present invention is not limited to the case of FIG.

As shown in Fig. 5, one TV field (e.g., normally 16.7 ms) is divided into a basic driving unit T composed of a writing period, a discharge sustaining period, and an erasing period, all of which are the same as in the case of FIG. Although it may be possible to have a length, it may be configured to have a different length as needed, even if the 256 gray scales are not necessarily divided into 255 as shown in FIG. As long as at least one basic driving unit T composed of the writing period, the discharge sustain period, and the erasing period is configured to constitute a subfield, it is only one variation of the present invention.

In order to easily understand the present invention, FIG. 5 illustrates a case where one TV field is divided into 255 driving units having the same length. In this case, each driving unit is combined to form each subfield required. For example, in the case of the darkest subfield 2 ⁰ , one basic driving unit T is formed. In addition, the second subfield 2 ¹ may be configured as two basic driving units T, and the third subfield 2 ² may be configured with four basic driving units T. FIG. In this manner, in the case of 256 gray scale implementation, the maximum size subfield 2 ⁷ may be configured of 128 basic driving units T. In this case, as shown in FIG. 5, 256 gray scales can be expressed in a total of 255 basic driving units (T) in one TV field. As a result, one driving unit (T) is about 65us as shown in FIGS. 5 and 8. It may be configured to be within a time.

6 illustrates the arrangement of the writing period A, the discharge sustaining period S, and the erasing period E in each driving unit T, and the start time of each subfield is 1 driving unit T for each line. For example, the case is sequentially arranged with as many differences as possible. The arrangement of the subfields per line can be variously changed. For example, the start time of the subfields per line can be changed by 2 or 3 driving units, or the order of the sequential arrangement can be changed. It will be apparent to those skilled in the art.

When the identification numbers 1 ... 256 assigned to each driving unit T shown in FIG. 5 follow the subfield arrangement of FIG. 6, the same identification number in each line is present in the same subfield and in the subfield. Indicates that it is a driving unit having the same position. That is, in FIG. 5, 1 corresponds to the first subfield, 2 to 3 corresponds to the second subfield, 4 to 7 corresponds to the third subfield, 8 to 15 refers to the fourth subfield, and 16 to 31 refers to the fifth subfield. For example, 32 to 63 are sixth subfields, 64 to 127 are seventh subfields, and 128 to 255 are eighth subfields.

FIG. 7 illustrates scan waveforms applied to each scan line for each scan line when the subfield arrangement and the driving unit division scheme of FIGS. 5 and 6 are used. In this embodiment, as shown in FIG. 7, data is written for the corresponding subfield during the writing period in the first driving unit in each subfield. During the writing period of another driving unit constituting the subfield, there is no need to write data for the corresponding subfield, so only the writing period exists and the writing operation does not proceed (in this case, the writing operation for some of the other scan lines of the panel). Will proceed). In addition, during the erasing period in the last driving unit in each subfield, data of the corresponding subfield is erased so that the next subfield can be driven. Similarly, since the image data of the corresponding subfield written in the first driving unit described above should not be erased during the erasing period of the other driving unit except the last driving unit, only the erasing period is secured and no erasing action is performed. With such a configuration, the write period of an arbitrary scan line is present between the sustain periods of other scan lines.

In the conventional driving method as shown in FIG. 2, since the sustain discharge process is performed at once for all the scan lines after the initialization and the write processes for all the scan lines are completed, the sustain discharge is concentrated at a specific time interval. An increase in panel temperature due to concentrated sustain discharge, deterioration of phosphors, and an afterimage problem in which an image of a previous screen remains on the screen remains. However, in the driving method of the present invention, one TV field has a plurality of basic driving units T, and each basic driving unit T is composed of a writing period, a sustain discharge period, and an erasing period, respectively. Since the period corresponding to the sustain discharge is distributed uniformly within one TV field, the above problem caused by the concentration of the sustain discharge does not occur.

The driving waveform in each driving unit T shown in FIG. 7 is shown in detail in FIG. 8. The writing period in the driving unit T is determined according to the number of bits of the gray scale (for example, 8 bits if 256 gray scales) to be displayed and the size of the panel. As illustrated in FIG. 8, in the case of implementing 256 gray levels in a VGA-level panel, it is sufficient to secure a writing period of more than a time period in which 16 unit address pulses can be arranged in total. Therefore, the length of the write period is not long, so that a faster write discharge is possible than in the prior art, and it is possible to prevent line-to-line variation due to the difference in time interval between the write period and the sustain discharge period.

In addition, in the sustaining period, the maximum number of possible pulses (for example, when four pulses are applied to one electrode, about 1020 pulses can be applied to one TV field per electrode) in order to increase the highest luminance. It is preferable.

In addition, as shown in Figs. 8 and 11, various erasing pulses may be used in the erasing period in order to enable a uniform erasing action to be performed in a short time with respect to the cell on which the discharge is turned on. For example, although a single erase pulse commonly used in the art may be used, it was designed by the present inventors in order to control the wall charge more efficiently and to perform a uniform erase function in a short time (Korean Patent Application No. 2002-76717). Reference) A method of applying a plurality of narrow pulses in succession can be used.

Through this driving scheme, the waveform of the writing period applied to each scan electrode is changed for each scan line as shown in FIG. 7, and the data writing process and the discharge sustain period are different for each scan electrode. As a result, the writing (address) process of the other scan electrode is performed while the discharge sustaining process of one scan electrode is performed as shown in FIG. 7. In addition, in the driving method of the present invention, as shown in FIG. 8, unlike the conventional technology such as the ADS driving method, the write discharge and the sustain are performed in the basic driving unit T having a short (eg, about 65us) time length. Since the discharge and the erase discharge occur, the time until the write period after the erasing action is short and the write discharge is made in a relatively uniform condition so that the write discharge can occur at a high speed. Short, a stable transition from address discharge to sustain discharge may occur.

11 illustrates an erase operation of multiple narrow pulses of the present invention.

In general, the PDP is composed of millions of cells, each of which is not the same electrical characteristics and has a slight deviation, that is, the wall voltage (Vw) formed by the discharge start voltage (Vb) and sustain discharge for each cell This little difference makes it difficult to obtain uniform and stable panel characteristics with a single pulse type erase waveform of the prior art in which an erase pulse is applied to all cells by applying one erase pulse. As another conventional technique for solving this problem, a method of applying a simple inclined erase pulse has been proposed, but in this case, the time required for erasing is long, the erase is not completely performed, and a partial wall charge remains. There is a problem.

The erase pulse using the multiple narrow pulse of the present invention devised to overcome this problem has a wall voltage formed because the voltage Vgap applied to the inside of the cell changes with time as the erase pulse is applied. Even in the case where the discharge start voltage differs from cell to cell, a stable erasing operation can be performed in a short time. That is, when the voltage Vgap applied to each cell satisfies Equation (1) below, the erasure discharge is started, and the erasing operation can be stably performed even if there is a deviation between the discharge start voltage and the wall charge for each cell.

Vw + Ve = Vgap> Vb (1)

In another embodiment of the erase waveform of the present invention, as shown in FIG. 14, after the erase pulse of the multiple narrow pulse, a pulse N having a negative polarity is applied to the scan electrode, and the multiple narrow pulse is applied once more. An erase waveform is constructed, and the erase operation between the scan electrode and the sustain electrode is performed in the first multiple narrow pulse T1, and the scan electrode Y, the discharge sustain electrode X, and the following negative scan pulse N are performed. At the same time, discharge is generated between the address electrode A and the wall charge is divided so that the erasing action is performed. In the second multi-width pulse T2, the remaining wall charges between the scan electrode and the address electrode are erased once more, so that the erase operation can be performed more stably. 15 and 16 illustrate examples of the basic driving unit T to which the erase waveform of FIG. 14 is applied as another embodiment of the driving method of the present invention. The erase waveforms illustrated in FIGS. 14, 15, and 16 illustrate cases where a plurality of narrow pulses are superimposed on a ramp waveform inclined at a predetermined slope. Here, the slope can be variously adjusted or optimized, as well as stable erasing, compared to the prior art in which a single erase pulse is applied even when only a plurality of narrow pulses are applied without overlapping a plurality of narrow pulses on the ramp waveform. It has been observed by the inventors that the property can be obtained.

9 shows a driving waveform in another embodiment of the present invention. In general, PDP uses a combination of subfields having different brightnesses as shown in FIG. 2 to express gray levels, and a certain number of subfields corresponding to a minimum bit to increase peak brightness. For example, in the case of representing 256 gray scales with 8 bits, the plurality of sustain pulses are configured to apply more than four sustain pulses, and a sufficient number (for example, 256 gray scales with 8 bits) are obtained so that sufficient luminance can be obtained when representing the highest brightness. In this case, about 1000 pulses (4 X 255 = 1020) are applied.

However, in this case, on the contrary, since the low gray level of the four pulses or less cannot be realized, the low gray level expression in the low gray level region has a problem that the low gray level expression is not smooth. To improve this, signal processing techniques such as error variance and dithering are generally used, but this method alone has a limitation in expressing low gradations. However, in the driving method of the present invention, by changing the basic driving unit T, a subfield expressing brightness smaller than 1 bit corresponding to the minimum subfield can be realized, so that a softer feeling in low gradation expression can be realized. Can give As shown in Fig. 9, in the driving method of the present invention, bits smaller than 1 bit (e.g., 0.25, 0.5, or 0.75 bit, etc. are required by adding a section for write discharge between the sustain periods of the basic driving unit. Implementation can be done very simply. At this time, for example, in the subfield corresponding to 0.5 bit, as shown in FIG. 10, the write discharge is performed between sustain discharges, thereby indicating brightness corresponding to half of the existing subfield corresponding to 1 bit.

In general, in the method of expressing gradation by a combination of subfields, such as a PDP, pseudo contour noise is inevitably generated when a moving image is expressed. In order to reduce this, generally, a method of arranging subfields is changed and a subfield corresponding to the highest brightness is divided into several subfields. However, in order to reduce the pseudo contour noise by applying such a change to the conventional ADS driving method, the initialization period and the writing period are added as the number of subfields increases, so that the duration of sustain discharge is relatively reduced, resulting in overall decrease in luminance. A fatal problem arises. However, in the driving method of the present invention, it is possible to arrange the order of the subfields differently for each scan line as shown in FIG. 12. Since the driving method is fundamentally different for each scanline, the rearrangement of these subfields does not cause any problem. By applying this, the pseudo contour noise can be greatly reduced.

In the above, as a specific embodiment to which the driving method of the present invention is applied, the case of implementing 256 gray scales through 8-bit image data for a VGA-level panel having 480 scan lines is illustrated. Naturally, it can be applied regardless of the number of bits and the specification of the panel. 17 shows how the basic drive unit T can be configured for the case where m bits of image data (that is, having m subfields) are used, and the number of scan lines exceeds 2 ^m −1. For example. In this case, even if the basic driving unit T corresponding to each scan line is sequentially arranged as shown in FIG. 5 (for example, 1 to 255 are sequentially arranged), 2 ^m −1 scan lines In the case of more than one scan line, the basic driving unit T having the same number is repeatedly displayed. Fig. 17 is a diagram showing a basic driving unit configuration in this case. Since the number of image data to be input during the writing period increases, it is necessary to secure the writing period in consideration of this. In the case of driving a panel having a very large number of lines, even though a sufficient writing period must be secured in the basic driving unit in this way, as compared with the prior art of FIG. Since the deviation between the time intervals of the erase period and the write period is significantly less, and the deviation between the time intervals between the write period and the sustain period is also much less, it is more advantageous, so that the driving method of the present invention has a great advantage in a high-quality large panel. .

18 shows another example of multiple narrow pulse waveforms usable for the erasing action in the driving method of the present invention. Unlike the example illustrated in FIG. 11, two or more narrow pulses are repeatedly applied and are modified waveforms that do not overlap with the bias voltage. Such waveforms are also used to implement the driving method of the present invention. It can be used in the erase process.

19 shows another example of the multiple narrow pulse waveforms usable for the erasing action in the driving method of the present invention. In this case, unlike the example of FIG. 18, in which the electrode potential is maintained at a constant base potential during the time interval between each narrow pulse and the narrow pulse, there is a floating potential at the electrode during the time interval between the narrow pulses. It is characterized in that it is applied, which means that the electrode is disconnected from the external circuit during the above-described time period and does not define its potential. In the above driving process, one narrow pulse is applied, the potential rises, is maintained at the peak potential for a predetermined time, and then after the potential falls, for example, by switching off the switching element of the drive circuit to the external circuit. It can be easily achieved through a method such as to open between the electrode and. Various modifications can be made in addition to the examples exemplified above, but all are merely simple design changes that fall within the scope of the technical idea of the present invention in that two or more narrow pulses are repeatedly applied to cause a stable erase operation.

In the case of using the driving waveform of the present invention, unlike the prior art, since the initialization pulse is not applied before the write discharge, since the background light does not occur, a high quality image having excellent contrast ratio can be obtained, but the initialization pulse is not used. It is necessary to consider to compensate for the deviation between the R, G, and B color cells that may occur. To this end, any method designed to compensate for variations between R, G, B, and cells may be applied, but a method of coating magnesium oxide (MgO), which is a material having a high secondary electron emission coefficient, on the lower panel fluorescent film of the panel may be applied. Can be. Fig. 13 shows the comparison of the measured operating margins of the driving voltages obtained by applying the driving waveforms of the present invention to the general panel (a) without such considerations and the panel (b) coated with a thin film of magnesium oxide on the fluorescent film. In the case of (b), the variation between the R, G, and B cells is greatly improved as compared with the conventional panel, and the operating voltage margin is expanded.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the technical idea of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

By using the driving method of the present invention, it is advantageous for high-speed driving by shortening the time taken from the address after the erasing action and minimizing the time required to move from the address to the sustain discharge, so that it can stably move from the write discharge to the sustain discharge. can do. In addition, since the sustain discharge period can be uniformly distributed in one TV field without being concentrated at a specific time, the power consumption is not concentrated at a specific time, so that the power circuit design is easy and the panel temperature is increased by continuous sustain discharge. It is possible to prevent deterioration of image quality such as phosphor deterioration and residual image. In addition, it is particularly easy to implement a subfield corresponding to fewer bits than a subfield corresponding to 1 bit, and thus it is possible to further improve low gray scale expression. In terms of pseudo contour noise, the configuration order of subfields can be arbitrarily changed for each scan line, so that pseudo contour noise can be easily reduced, and high quality images can be realized.

Claims (7)

A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more subfields for implementing gradation by combination, each of the subfields is divided into one or more driving units (T), and each of the driving units (T) is temporally A separate write period, sustain period, and erase period, Writing data for the corresponding subfield during the writing period of the first of the driving units (T) constituting the subfield; And Erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield; Here, the writing period in the driving unit T is a period equal to or more than a time obtained by multiplying the pulse width of the unit address pulse by at least the total number of the subfields, and during the sustaining period, a sustain pulse is alternately applied to the scan electrode and the sustain electrode. Applying a predetermined waveform to the scan electrode to generate an erase discharge in the erase period; The waveform applied to the scan electrode for the erase discharge is a waveform having one or more sections in which a plurality of narrow pulses are repeated, the width of each narrow pulse is less than 300ns.  A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more subfields for implementing gradation by combination, each of the subfields is divided into one or more driving units (T), and each of the driving units (T) is temporally A separate write period, sustain period, and erase period, Writing data for the corresponding subfield during the writing period of the first of the driving units (T) constituting the subfield; And Erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield; Here, the writing period in the driving unit T is a period equal to or more than a time obtained by multiplying the pulse width of the unit address pulse by at least the total number of the subfields, and during the sustaining period, a sustain pulse is alternately applied to the scan electrode and the sustain electrode. In the erase period, a predetermined waveform for generating an erase discharge is applied to the scan electrode. The waveform applied to the scan electrode for the erase discharge is a waveform having one or more sections in which a plurality of narrow pulses are repeated, and a section in which a pulse having a negative polarity is applied between sections in which the plurality of narrow pulses are repeated. Characterized in that inserted Driving method of plasma display. A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more subfields for implementing gradation by combination, each of the subfields is divided into one or more driving units (T), and each of the driving units (T) is temporally A separate write period, sustain period, and erase period, Writing data for the corresponding subfield during the writing period of the first of the driving units (T) constituting the subfield; And Erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield; Here, the writing period in the driving unit T is a period equal to or more than a time obtained by multiplying the pulse width of the unit address pulse by at least the total number of the subfields, and during the sustaining period, a sustain pulse is alternately applied to the scan electrode and the sustain electrode. Applying a predetermined waveform to the scan electrode to generate an erase discharge in the erase period; The waveform applied to the scan electrode for the erase discharge is a waveform having one or more sections in which a plurality of narrow pulses are repeated, and the plurality of narrow erase pulses are superimposed on a ramp waveform that increases with time. Driving method of plasma display. A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more subfields for implementing gradation by combination, each of the subfields is divided into one or more driving units (T), and each of the driving units (T) is temporally A separate write period, sustain period, and erase period, Writing data for the corresponding subfield during the writing period of the first of the driving units (T) constituting the subfield; And Erasing data for the corresponding subfield during the erasing period of the last one of the driving units T constituting the subfield; The arrangement order of the subfields constituting the one frame according to the scan line is different. Driving method of plasma display. A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more driving units T, each of the driving units T including a writing period, a sustaining period, and an erasing period separated in time, In the erase period, a predetermined waveform for generating erase discharge is applied to the scan electrode, The waveform applied to the scan electrode for the erase discharge is a waveform having one or more sections in which a plurality of narrow pulses are repeated. The width of each narrow pulse is characterized in that less than 300ns Driving method of plasma display. A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more driving units T, each of the driving units T including a writing period, a sustaining period, and an erasing period separated in time, In the erase period, a predetermined waveform for generating erase discharge is applied to the scan electrode, The waveform applied to the scan electrode for the erase discharge is a waveform having one or more sections in which a plurality of narrow pulses are repeated. And a section in which a pulse having a negative polarity is applied between sections in which the plurality of narrow pulses are repeated. Driving method of plasma display. A plurality of scan electrodes and a plurality of sustain electrodes corresponding to each of the scan electrodes, a plurality of address electrodes orthogonal to the scan electrodes, and a plurality of scan electrodes formed at respective points orthogonal to the scan electrodes A driving method of an alternating current plasma display for displaying predetermined image information on an alternating current plasma display panel including discharge cells, One frame of the image information is divided into one or more driving units T, each of the driving units T including a writing period, a sustaining period, and an erasing period separated in time, In the erase period, a predetermined waveform for generating erase discharge is applied to the scan electrode, The waveform applied to the scan electrode for the erase discharge is a waveform having one or more sections in which a plurality of narrow pulses are repeated. The plurality of narrow erase pulses are applied in superimposition with a ramp waveform that increases with time. Driving method of plasma display.

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