KR100647706B1 - Apparatus of driving plasma display panel - Google Patents

Abstract

A driving device of a display panel is provided to reduce a memory space by displaying subfield data of at least one gray scale by time-division dithering of the subfield data of the other gray scales and forming a subfield table only with the subfield data of the gray scales to be displayed directly. An input image signal is divided by a frame that is a display cycle. Multiple subfields for time-division displaying the gray scales are formed in each frame. Subfield data about on/off information in each subfield forming the frame are formed for each gray scale. A driving device(30) drives a display panel according to the subfield data. The gray scales are divided into the subfield data gray scale forming the subfield data and the dithering gray scale displayed by time-division dithering the subfield data gray scales. A subfield data table(321c) storing subfield data information of the subfield data gray scale and a dithering table(321b) storing the dithering information of the dithering gray scale are stored separately.

Description

Apparatus of driving plasma display panel

1 is a perspective view showing an internal structure of a three-electrode surface discharge plasma display panel to which a driving device of a display panel according to the present invention is applied.

FIG. 2 is a block diagram illustrating an apparatus for driving a plasma display panel for driving the plasma display panel of FIG. 1.

3 is a timing diagram illustrating a method of driving a plasma display panel in which a unit frame is configured by driving a plurality of subfields.

FIG. 4 is a timing diagram illustrating driving signals applied to respective electrode lines with respect to a subfield as a driving method of the plasma display panel driving apparatus according to the present invention.

FIG. 5 is a block diagram schematically showing a driving device of the plasma display panel of FIG. 2 as a preferred embodiment of the present invention.

FIG. 6 is a diagram schematically showing subfield data and dithering data sequentially formed for all gray levels.

7A is a diagram schematically illustrating a subfield data table according to the present invention.

7B schematically illustrates dithering information according to the present invention.

8 is a block diagram illustrating an interior of a logic controller in the driving apparatus of the plasma display panel of FIG. 2.

9 is a flowchart schematically illustrating a method of driving a plasma display panel as a preferred embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

1: plasma display panel,

20, 30: drive of the plasma display panel,

22: logic controller, 23: address driver,

24: X drive unit, 25: Y drive unit,

320: output gradation generator, 321, 521: subfield generator.

The present invention relates to an apparatus for driving a display panel, and more particularly, to an apparatus for driving a display panel in which a plurality of subfields for time division gray scale display exist for each frame as a display period.

As flat panel display devices, plasma display panels (PDPs), which are easy to manufacture large panels, have attracted attention. A plasma display panel is a display device that displays an image by using a discharge phenomenon. In general, a plasma display panel can be classified into a direct current type and an alternating current type according to the type of driving voltage. Due to the disadvantages, the development of the AC plasma display panel has been made a lot.

An AC plasma display panel includes a three-electrode AC surface discharge type plasma display panel having three electrodes and driven by an AC voltage. A typical three-electrode surface discharge type plasma display panel is composed of a multi-layered plate, which is spatially advantageous because it can provide a thinner, lighter, and wider screen than a conventional cathode ray tube (CRT).

The plasma display panel includes a plurality of display cells formed in a region where the sustain electrode and the address electrode cross each other, and one display cell includes three discharge cells (red, green, and blue), and discharges the discharge cells. The gray level of the image is expressed by adjusting the state.

In order to express the gray scale of the plasma display panel, one frame applied to the plasma display panel may be configured with eight subfields having different emission counts to express 256 gray scales. That is, in the case where the image is to be displayed with 256 gray levels, the frame period (16.67 ms) corresponding to 1/60 second is divided into eight subfields. There is a reset period, an address period, and a sustain discharge period in each of the sub-fields to drive the plasma display panel.

In this case, a subfield table is constructed of information on subfields that will cause address discharge and sustain discharge and information on subfields that will not generate, and information on the subfield table for each input grayscale to be expressed. Each subfield can be driven by.

A subfield table is constructed and stored in the memory for all input grayscales. For this purpose, when each subfield is represented by 16 bits, a memory space of at least 16 gray levels is required. For example, when an image is represented by 256 gray levels, a memory of 16 bits x 256 gray levels = 4096 bits is required.

If a plurality of subfield tables is required as necessary, a memory space of the number of subfield tables x the number of representation gray scales x 16 bits is required. For example, when 10 subfield tables are required and an image is represented with 256 gray levels, a memory of 10 x 16 bits x 256 gray levels = 40960 bits is required.

That is, a large amount of memory space for storing the subfield table is required, which increases the production cost of the plasma display panel.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and displays at least one subfield data of one or more gray levels by time division dithering of subfield data of another gray level, and directly converts a subfield table using only subfield data of gray levels directly displayed. It is an object of the present invention to provide a display panel driving apparatus capable of reducing a memory space required for storing subfield data.

The display panel driving apparatus according to the present invention for achieving the above object divides an input video signal into a frame as a display period, and there are a plurality of subfields for time division gray scale display for each frame, and for each gray scale. Subfield data of on / off information in each of the subfields constituting the frame is configured, and driving the display panel according to the subfield data, the subfield data gradation forming the subfield data. And a dithering gray level indicated by time division dithering of the subfield data grayscales, and a subfield data table storing subfield data information of the subfield data grayscale and a dithering table storing dithering information of the dithering grayscale are separated. Stored.

Preferably, information about whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index.

An output gray scale generator for generating an output gray scale from the input video signal; And a subfield generator for generating the subfield data corresponding to the output grayscale.

Preferably, the subfield generator generates the subfield data according to the grayscale index of the output grayscale.

According to another aspect of the present invention, a display panel driving apparatus includes a display panel in which discharge cells are formed by an X electrode, a Y electrode, and an address electrode, and divides an input image signal into frames as a display period, and time-division gray scale display for each frame. There are a plurality of subfields for, subfield data of on / off information in each subfield constituting the frame is configured for each grayscale, and the display panel is driven according to the subfield data. A logic controller for generating a drive control signal including an X drive control signal, a Y drive control signal, and an address drive control signal according to the video signal; and applying a drive signal according to the X drive control signal to the X electrodes. An X driving unit and a driving signal according to the Y driving control signal to the Y electrodes A subfield data gradation and a subfield for forming the subfield data, the subfield data including a Y driver for applying and an address driver for applying a driving signal according to the address driving control signal to the address electrodes; The subfield data of each gray level according to the input image signal is generated by dividing the dither gray level displayed by time division dithering of the field data gray levels.

Preferably, the subfield data table storing the subfield data information of the subfield data gradation and the dither table storing the dithering information of the dithering gradation are separately stored.

Preferably, information about whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index.

Preferably, the logic controller includes an output gray scale generator that generates an output gray scale from the input video signal, and a subfield generator that generates the subfield data corresponding to the output gray scale.

According to another aspect of the present invention, there is provided a method of driving a display panel, which divides an input image signal into frames as a display period, and includes a plurality of subfields for time division gray scale display for each frame, and configures the frame for each gray scale. Subfield data of on / off information in each of the subfields is configured, and by driving a display panel according to the subfield data, the subfield data grayscale and the subfield data forming the grayscale subfield data. The dithering gray level is divided by a time division dithering of gray levels, and a subfield data table storing subfield data information of the subfield data grayscale and a dithering table storing dithering information of the dithering grayscale are separately stored.

Preferably, information about whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index.

In addition, the display panel driving method,

(a) generating an output gray scale from the input video signal;

(b) referring to a gray scale index corresponding to the output gray scale;

(c) determining, according to the gray scale index, a table to be referred to for generating the subfield data;

(d) if the output gradation is a dithering gradation, re-determining an output gradation with reference to the dithering table;

(e) generating the subfield data corresponding to the output grayscale with reference to the subfield data table; And

(f) preferably driving the display panel according to the subfield data.

According to the present invention, storage of subfield data by displaying at least one subfield data of one or more gray levels by time division dithering of subfield data of another gray level, and constructing a subfield table with only subfield data of gray levels directly displayed The memory space required for this can be reduced.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an internal perspective view showing the structure of a three-electrode surface discharge plasma display panel.

Referring to the drawings, between the front and rear glass substrates 10 and 13 of the surface discharge plasma display panel 1, the address electrode lines A _{R1 to} A _Bm , the dielectric layers 11 and 15, and the Y electrode line (Y ₁ to Y _n ), X electrode lines (X ₁ to X _n ), fluorescent layer 16, partition wall 17, and magnesium monoxide (MgO) layer 12 as a protective layer are provided.

The address electrode lines A _{R1 to} A _Bm are formed in a predetermined pattern on the front side of the rear glass substrate 13. The lower dielectric layer 15 is applied to the entire surface in front of the address electrode lines A _{R1 to} A _Bm . In front of the lower dielectric layer 15, barrier ribs 17 are formed in a direction parallel to the address electrode lines A _{R1 to} A _Bm . These partitions 17 function to partition the discharge area of each discharge cell 14 and to prevent optical cross talk between each discharge cell 14. The fluorescent layer 16 is formed on the inner surface of the space formed between the lower dielectric layer 15 and the partition walls 17 formed on the rear glass substrate 13.

The X electrode lines X ₁ to X _n and the Y electrode lines Y ₁ to Y _n have a constant pattern on the rear side of the front glass substrate 10 to be orthogonal to the address electrode lines A _{R1 to} A _Bm . Is formed. Each intersection sets a corresponding discharge cell 14. Each X electrode line (X _{1 to} X _n ) and each Y electrode line (Y _{1 to} Y _n ) are combined with a transparent electrode line made of a transparent conductive material such as indium tin oxide (ITO) and a metal electrode line for increasing conductivity. Is formed. Here, the X electrode lines X ₁ to X _n become sustain electrodes in the respective discharge cells 14, and the Y electrode lines Y ₁ to Y _n correspond to scan electrodes in the respective discharge cells 14. And become an address electrode in the discharge cell 14 of each of the address electrode lines A _{R1 to} A _Bm .

2 is a block diagram illustrating a driving apparatus of a plasma display panel.

Referring to the drawings, the driving device 20 of the plasma display panel 1 includes an image processor 21, a logic controller 22, an address driver 23, an X driver 24, a Y driver 25, and an external device. And a luminance detector 26. The image processor 21 converts an external analog image signal into a digital signal, and thus internal image signals, for example, 8-bit red (R), green (G), and blue (B) image data, clock signals, vertical and horizontal, respectively. Generate sync signals. The logic controller 22 generates driving control signals S _A , S _Y , and S _X according to an internal image signal from the image processor 21.

In this case, the driving unit such as the address driver 23, the X driver 24, and the Y driver 25 receives input from the driving control signals S _A , S _Y , and S _X , and generates respective driving signals. The applied driving signal to each of the electrode lines.

That is, the address driver 23 processes the address signal S _A among the drive control signals S _A , S _Y , and S _X from the logic controller 22 to generate a display data signal, and generates the displayed display. The data signal is applied to the address electrode lines. The X driver 24 processes the X driving control signal S _X from the driving control signals S _A , S _Y , and S _X from the logic controller 22 and applies the X driving control signal S _X to the X electrode lines. The Y driver 25 processes the Y driving control signal S _Y among the driving control signals S _A , S _Y , and S _X from the logic controller 22 and applies the Y driving control signal S _Y to the Y electrode lines.

The driving apparatus 20 of the plasma display panel according to the present invention divides an input image signal into frames as a display period, and there are a plurality of subfields for time division gray scale display for each frame, and the frame is displayed for each gray scale. Subfield data of on / off information in each of the constituting subfields is configured, and the display panel is driven according to the subfield data.

In this case, the grayscales are divided into subfield data grayscales forming subfield data and dithering grayscales represented by temporal dithering of the subfield data grayscales, and the subfields storing subfield data information of the subfield data grayscales. The data table and the dithering table for dithering information of the dithering gray level are stored separately. Further, information on whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index.

To this end, the driving apparatus 20 of the plasma display panel includes an output gray scale generator (320 in FIG. 5) for generating an output gray scale from the input image signal, and a sub for generating the subfield data corresponding to the output gray scale. And a field generator (320 in FIG. 5). Here, the output gray scale generator 320 (in FIG. 5) and the subfield generator (321 in FIG. 5) may be included in the logic controller 22.

3 is a timing diagram illustrating a method of driving a plasma display panel in which a unit frame is configured by driving a plurality of subfields.

Referring to the drawing, the unit frame FR is divided into eight subfields SF1 to SF8 to realize time division gray scale display. Each subfield SF1 to SF8 is divided into reset periods R1 to R8, address periods A1 to A8, and sustain discharge periods S1 to S8.

The luminance of the plasma display panel is proportional to the length of the sustain discharge periods S1 to S8 occupied in the unit frame. The length of the sustain discharge cycles S1 to S8 occupied in the unit frame is 255T (T is the unit time). At this time, a time corresponding to 2 ⁿ is set in the sustain discharge period Sn of the nth subfield SFn. Accordingly, if the subfield to be displayed among the eight subfields is appropriately selected, 256 gray levels may be displayed including all zero (zero) grays not displayed in any of the subfields.

4 is a timing diagram illustrating driving signals applied to respective electrode lines with respect to a subfield as a driving method of the display panel driving apparatus according to the present invention.

In FIG. 4, reference numeral S _{AR1 ..ABm} denotes a driving signal applied to each address electrode line (A _R1 to A _Bm of FIG. 1), and S _{X1 ..Xn} denotes X electrode lines (X ₁ to X of FIG. 1). _n ), and S _Y1 to S _Yn indicate a drive signal applied to each Y electrode line (Y ₁ to Y _{n in} FIG. 1).

Referring to the drawings, in the reset period PR of the unit sub-field SF, first, the voltage applied to the X electrode lines X ₁ to X _n is converted from the ground voltage V _G to the second voltage V _S. For example, it continuously increases to 155 volts (V). Here, the ground voltage V _G is applied to the Y electrode lines Y ₁ to Y _n and the address electrode lines A _R1 to A _Bm . Accordingly, between the X electrode lines X ₁ to X _n and the Y electrode lines Y ₁ to Y _n , and the X electrode lines X ₁ to X _n and the address electrode lines A ₁ to A _A weak discharge occurs between _m ) and negative wall charges are formed around the X electrode lines X ₁ to X _n .

The Next, Y electrode lines (Y ₁ ~ Y _n) voltage to the second voltage applied to the (V _S), for example, the third voltage (V _SET than the second voltage (V _S) from 155 volt (V) The maximum voltage (V _SET + V _S ), which is as high as), continues to rise to, for example, 355 volts (V). Here, the ground voltage V _G is applied to the X electrode lines X ₁ to X _n and the address electrode lines A _R1 to A _Bm . Accordingly, a weak discharge occurs between the Y electrode lines Y ₁ to Y _n and the X electrode lines X ₁ to X _n , while the Y electrode lines Y ₁ to Y _n and the address electrode lines are formed. Weak discharge occurs between (A _R1 and A _Bm ).

Next, while the voltage applied to the X electrode lines X ₁ to X _n is maintained at the second voltage V _S , the voltage applied to the Y electrode lines Y ₁ to Y _n is second. It continues to fall from voltage V _S to ground voltage V _G. Here, the ground voltage V _G is applied to the address electrode lines A _R1 to A _Bm .

Leads in the address period (PA), the address is applied to a display data signal of the address pulse to the electrode line, the second voltage (V _S) lower fourth voltage (V _SCAN) to bias the Y-electrode line than the (Y ₁ As the scan signals of the scan pulses of the ground voltage V _G are sequentially applied to ˜Y _n ), smooth addressing may be performed.

At this time, the display data signal applied to each of the address electrode lines A _R1 to A _{Bm is} supplied with the positive address voltage V _A when the discharge cell is selected and the ground voltage V _G when the discharge cell is not selected. Accordingly, when the display data signal of the positive address voltage V _A is applied while the scan pulse of the ground voltage V _G is applied, wall charges are formed by the address discharge in the corresponding discharge cell. Wall charges do not form. In addition, the second voltage V _S is applied to the X electrode lines X ₁ to X _{n for} more accurate and efficient address discharge.

In the sustain discharge period PS, the display sustain pulse of the second voltage V _S is alternately applied to all the Y electrode lines Y ₁ to Y _n and the X electrode lines X ₁ to X _n . In the corresponding address period PA, a discharge for maintaining the display occurs in discharge cells in which wall charges are formed.

FIG. 5 is a block diagram schematically showing a driving device of the plasma display panel of FIG. 2 as a preferred embodiment of the present invention. FIG. 6 is a diagram schematically showing subfield data and dithering data sequentially formed for all gray levels. 7A is a diagram schematically illustrating a subfield data table according to the present invention. 7B schematically illustrates dithering information according to the present invention.

Referring to the drawing, the driving device 30 of the plasma display panel includes an output gray scale generator 320 for generating an output gray scale from the input image signal, and a subfield for generating the subfield data corresponding to the output gray scale. The generator 321 is provided. Here, the output gray scale generator 320 and the subfield generator 321 may be configured to be included in the logic controller 22 of FIG. 2.

The driving device 30 of the plasma display panel divides an input image signal into frames as a display period, and there are a plurality of subfields for time division gray scale display for each frame, and each frame constituting the frame for each gray scale. Subfield data of on / off information in subfields of the subfield is configured, and drives the display panel according to the subfield data.

In this case, the grayscales are divided into subfield data grayscales forming subfield data and dithering grayscales represented by temporal dithering of the subfield data grayscales. The subfield data table 321b storing the subfield data information of the subfield data gradation and the dithering table 321c storing the dithering information of the dithering gradation are separately stored. Further, information on whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index 321a.

The subfield generation unit 321 generates subfield data for each grayscale by referring to the subfield data table 321b or the dither table 321c for each grayscale according to the grayscale index 321a. To perform gradation display.

In order to generate the subfield data of the gradation to be expressed, the subfield data table is sequentially formed for the mode gradation, and the subfield data of the gradation is configured for the output gradation to be displayed with reference to the subfield data table. Can be.

However, a pseudo contour occurs or the number of subfields turned on in a small gradation becomes larger than the number of subfields in a larger gradation, and the gradation representation is designed mainly on the luminance represented by the sustaining light, but is represented by the address light. The luminance is affected, which may cause a problem in gray scale display.

Accordingly, as shown in FIG. 6, the subfield data of the grayscales such as the grayscales 4, 8, 9, 10, and 12 may not be directly used, and other grays may be divided and used in time. In the case of the embodiment shown in FIG. 6, the gradation 4 divides the gradation 3 and the gradation 5 in time, the gradations 8, 9, and 10 divide the gradation 7 and the gradation 11 in time, and the gradation 12 divides the gradation 11 and the gradation 13. It can be expressed through time division dithering.

However, in this case, when subfield data and dithering data that are sequentially formed for all gray levels are formed and stored as one table, the amount of data to be stored increases as shown in FIG. 6, thereby increasing the memory space occupied. Can be.

Thus, in the embodiment in FIG. 6, the subfield data table 321c of FIG. 5 forms subfield data of gray levels not represented by the subfield data shown in FIG. 6 and represented by time division dithering. can do. In addition, dither information of gray levels not represented in the subfield data table 321c of FIG. 5 may be formed as a dither table 321b of FIG. 5.

In addition, for each of the gray levels, information on whether the gray level represented by the subfield data table or the gray level represented by the dithering information may be stored as a gray index. In this case, when a specific output grayscale is to be expressed, the frame is driven by the corresponding subfield data when the grayscale is represented by the subfield data table by referring to the grayscale index of the grayscale index.

In addition, with reference to the gray scale index of the gray scale, the gray scale represented by the dithering information is driven by temporal overlap of several frames by time division dithering of the gray scales by the dithering information. At this time, the gray level represented in each frame is re-determined by the dithering information, and subfield data of the corresponding gray level is generated with reference to the subfield data table for each frame.

Therefore, the gray scales having problems in the gray scale expression can be expressed by time division dithering, thereby improving the gray scale expressing power. In addition, since the subfield data table is formed by omitting the gray level subfield data that is not actually used, the memory space required for storing the subfield data table can be saved.

8 is a block diagram illustrating an interior of a logic controller in the driving apparatus of the plasma display panel of FIG. 2.

Referring to the drawings, the logic controller 22 of FIG. 2 includes a clock buffer 55, a synchronization controller 526, a gamma correction unit 51, an error diffusion unit 512, and first-in first-out. Memory 511, subfield generator 521, subfield matrix 522, matrix buffer 523, memory controller 524, average load factor calculator 53, number of sustain pulses 58 ), Frame-memory (RFM1, ..., BFM3), reordering unit 525, EPIROM 54a, I2C serial communication interface 54b, timing-signal generator 54c, and XY control unit ( 54).

The clock buffer 55 converts the 26-megahertz (MHz) clock signal CLK26 from the image processor (21 of FIG. 2) into a 40-megahertz (MHz) clock signal CLK40 and outputs the converted signal. The synchronization adjustment unit 526 includes a 40-megahertz (MHz) clock signal CLK40 from the clock buffer 55, an initialization signal RS from the outside, and a horizontal synchronization signal from the image processing unit (21 in FIG. 2). (HSYNC) and the vertical sync signal VSYNC are input. The synchronization adjusting unit 526 outputs the horizontal synchronization signals HSYNC1, HSYNC2, and HSYNC3 in which the input horizontal synchronization signal HSYNC is delayed by a predetermined number of clocks, respectively, while the input vertical synchronization signal VSYNC is predetermined. The vertical synchronization signals VSYNC2 and VSYNC3 are respectively delayed by the number of clocks.

The image data R, G, and B input to the gamma correction unit 51 has a reverse nonlinear input / output characteristic in order to correct the nonlinear input / output characteristics of the cathode ray tube. Therefore, the gamma correction unit 51 processes the image data R, G, and B of the reverse nonlinear input and output characteristics to have the linear input and output characteristics. The error diffusion unit 512 reduces the data transmission error by using the first-in first-out memory 511 to move the position of the maximum sign bit that is the boundary bit of the image data R, G, and B.

The gamma correction unit 51 converts an input video signal having a non-linear gradation display characteristic into image data having a linear gradation input / output characteristic by gamma correction, and comprises a plurality of gamma correction tables formed according to the relationship between the input video signal and the image data. The gamma correction is performed by referring to one of the gamma correction tables.

The subfield generator 521 converts 8-bit image data R, G, and B into 8-bit image data R, G, and B, respectively, corresponding to the number of subfields. For example, when grayscale driving is performed with 14 subfields in a unit frame, after converting 8-bit image data R, G, and B into 14-bit image data R, G and B, respectively, In order to reduce a data transmission error, 16 bits of image data R, G, and B are output by adding invalid data '0' of a maximum value bit (MSB) and a minimum value bit (Least Significant Bit).

The subfield matrix unit 522 rearranges 16-bit video data R, G, and B into which data of different subfields is simultaneously input, so that data of the same subfield is simultaneously output. The matrix buffer unit 523 processes the 16-bit image data R, G, and B from the subfield matrix unit 522 and outputs the 32-bit image data (R, G, B).

The memory control unit 524 may include a red memory control unit for controlling three red frame R memories (RFM1, RFM2, and RFM3), and three green (G) frame memory memories (GFM1, GFM2, A green memory control unit for controlling GFM3) and a blue memory control unit for controlling the three blue frame B memories (BFM1, BFM2, BFM3). Frame data from the memory controller 524 is continuously output in units of frames and input to the rearrangement unit 525.

An output gray scale generator 320 (in FIG. 5) generates an output gray scale from the input image signal, and the subfield generator 521 generates the subfield data corresponding to the output gray scale. In this case, the output gray scale generator 320 of FIG. 5 may include a gamma corrector 51 and an error diffuser 512.

In the drawing, reference numeral EN denotes an enable signal generated from the XY controller 54 and input to the memory controller 524 to control the data output of the memory controller 524. Also, reference numeral S _SYNC is generated from the XY control unit 54 to control data input / output in units of 32-bit slots in the memory control unit 524 and the rearrangement unit 525. The slot synchronization signal input to the column unit 525 is indicated. The rearrangement unit 525 rearranges and outputs 32-bit image data R, G, and B from the memory control unit 524 to match the input format of the address driver 23 (in FIG. 2).

In the YEPROM 54a, timing control data according to a driving sequence of the X electrode lines (X ₁ to X _n of FIG. 1) and the Y electrode lines (Y ₁ to Y _n of FIG. 1) are stored. The discharge recovery control data APC from the number control unit 58 of the sustain pulses and the timing control data from EPIROM 54a are transmitted through the I ² C serial communication interface 54b to the timing-signal generator 54c. Is entered. The timing-signal generator 54c operates according to the input discharge count control data APC and the timing control data to generate the timing-signal. The XY control unit 54 operates in accordance with the timing-signal from the timing-signal generator 54c to output the X drive control signal S _X and the Y drive control signal S _Y.

The average load factor calculator 53 calculates an average signal level ASL from the load factor expressed by the number of discharge cells that are turned on among the total number of discharge cells. The number control unit 58 of the sustain pulses may perform automatic power control by forming sustain discharge number data tables that are formed in inverse proportion to the load ratio. At this time, the number control unit 58 of the sustain pulse generates a discharge count control data (APC) corresponding to the average signal level (ASL), thereby performing the function of automatic power control to make the power consumption constant in each frame. . In the present embodiment, the number control unit 58 of the sustain pulse per line may perform the automatic power control function when the load ratio of the frame exceeds 30%.

9 is a flowchart schematically illustrating a method of driving a plasma display panel as a preferred embodiment of the present invention.

Referring to the drawing, according to the driving method 900 of the plasma display panel, the input image signal is divided into frames as a display period, and there are a plurality of subfields for time division grayscale display for each frame, and for each grayscale, Subfield data of on / off information in respective subfields constituting the frame is configured, and the display panel is driven according to the subfield data.

In this case, the grayscales are divided into subfield data grayscales forming subfield data and dithering grayscales represented by temporal dithering of the subfield data grayscales. The subfield data table storing the subfield data information of the subfield data gradation and the dithering table storing the dithering information of the dithering gradation are separately stored. Information of whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a grayscale index.

The driving method 900 of the plasma display panel is performed by the driving apparatus of the plasma display panel of FIG. 5, and performs a function according to the invention described with reference to FIG. 5.

To this end, the driving method 900 of the plasma display panel includes generating an output gray scale from the input image signal (910); Referring to a gray level index corresponding to the output gray level (920); Determining (930) a table to be referred for generating the subfield data according to the gray scale index; Re-determining (940) the output grayscale with reference to the dithering table if the output grayscale is a dithering grayscale; Generating (950) the subfield data corresponding to the output grayscale with reference to the subfield data table; And driving 960 a display panel according to the subfield data.

The plasma display panel, its driving device, and the driving method shown in FIGS. 1 to 4 are just one embodiment to which the driving method of the plasma display panel according to the present invention can be applied, and various other plasma display panels and its driving method. Applicable to the device and the driving method.

According to the display panel driving apparatus according to the present invention, the subfield data of at least one gray level is displayed by temporal dithering of subfield data of another gray level, and the subfield table is composed of only the subfield data of gray levels directly displayed. By doing so, the memory space required for storing the subfield data can be reduced.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it is merely an example, and those skilled in the art may realize various modifications and equivalent other embodiments therefrom. I can understand. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

Claims (13)

The input image signal is divided into frames as a display period, and there are a plurality of subfields for time-division gray level display for each frame, and for each gray level, on / off information of each subfield constituting the frame is displayed. Field data is configured, and the display panel is driven in accordance with the subfield data. Dividing the grayscales into subfield data grays forming subfield data and dithering grays represented by time division dithering of the subfield data grays, And a subfield data table storing subfield data information of the subfield data gradation and a dithering table storing dithering information of the dithering gradation. The method of claim 1, And information on whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index. The method of claim 2, And a subfield data is generated for each of the grayscales by referring to the subfield data table or the dithering table for each grayscale, and to perform grayscale display. The method of claim 2, An output gray scale generator for generating an output gray scale from the input video signal; And And a subfield generator for generating the subfield data corresponding to the output gray level. The method of claim 4, wherein And the subfield generator generates the subfield data according to the grayscale index of the output grayscale. For a display panel in which discharge cells are formed by the X electrode, the Y electrode, and the address electrode, the input image signal is divided into frames as a display period, and each subframe has a plurality of subfields for time division gray scale display, and each gray scale. Subfield data of on / off information in respective subfields constituting the frame is configured, and the display panel is driven in accordance with the subfield data. A logic controller for generating a drive control signal including an X drive control signal, a Y drive control signal, and an address drive control signal according to the video signal; and X for applying a drive signal according to the X drive control signal to the X electrodes. A driving unit for applying a driving signal according to the Y driving control signal to the Y electrodes, and an address driving unit for applying a driving signal according to the address driving control signal to the address electrodes; In the logic controller, the grayscales are divided into subfield data grayscales forming subfield data and dithering grayscales represented by time division dithering of the subfield data grayscales, and the subfield data of each grayscale according to the input image signal. Driving device of the display panel to create a. The method of claim 6, And a subfield data table storing subfield data information of the subfield data gradation and a dithering table storing dithering information of the dithering gradation. The method of claim 6, And information on whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index. The method of claim 8, The logic control unit, An output gray scale generator for generating an output gray scale from the input video signal; And a subfield generator for generating the subfield data corresponding to the output gray level. The method of claim 9, And the subfield generator generates the subfield data according to the grayscale index of the output grayscale. The input image signal is divided into frames as a display period, and there are a plurality of subfields for time-division gray level display for each frame, and for each gray level, on / off information of each subfield constituting the frame is displayed. Field data is configured, and the display panel is driven in accordance with the subfield data. Dividing the grayscales into subfield data grays forming subfield data and dithering grays represented by time division dithering of the subfield data grays, And a difield table for storing subfield data information of the subfield data gradation and a dither table for dithering the dithering gradation. The method of claim 11, And information on whether each of the grayscales is the subfield data grayscale or the dithering grayscale is stored as a gray scale index. The method of claim 12, (a) generating an output gray scale from the input video signal; (b) referring to a gray scale index corresponding to the output gray scale; (c) determining, according to the gray scale index, a table to be referred to for generating the subfield data; (d) if the output gradation is a dithering gradation, re-determining an output gradation with reference to the dithering table; (e) generating the subfield data corresponding to the output grayscale with reference to the subfield data table; And and (f) driving the display panel according to the subfield data.

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