KR100246238B1 - Plasma display panel's driving device - Google Patents

Abstract

According to an embodiment of the present invention, a screen division method for dividing and driving a screen for high-speed implementation of image data includes: a memory unit storing Y sustain electrode driving IC to be driven by a main controller and information on display lines; The present invention relates to a driving apparatus of a plasma display panel, in which the implementation of the controller is simplified and the driving thereof is easy by using (EPROM).

Description

Driving device of plasma display panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel (hereinafter referred to as a PDP). In particular, in a screen division method for splitting a screen for high-speed implementation of image data, a memory unit is implemented by using an externally mounted EPROM. The driving apparatus of the plasma display panel is simplified and the driving thereof becomes easy.

As the flat display device is not only thin, but also can realize a large display screen, its use range has been rapidly expanded and research on it is being actively conducted. In particular, multi-faceted research is underway to realize high-speed driving of PDPs, which has recently been spotlighted due to the trend of flattening and large screens.

Briefly, the driving principle of PDP is as follows. First, referring to FIG. 1, which shows the distribution of subframes over time, a technique of providing PDP gradation is divided into time periods by dividing one frame period of a displayed screen into a plurality of subframes SF1 to SF8. Adds to the cell's brightness by having a specific cell lighting time. A typical prior art which gives the gradation of the visible luminance is that after the cells on a single horizontal display line (hereinafter referred to as line) Y1 are selectively written, i.e., addressed, the next subsequent lines Y2, Y3 .... YN It is optionally written to the cells in sequence. In this case, the gradation of the visible luminance, that is, the gray scale is proportional to the number of sustain pulses illuminating the cells in one frame. Thus, the gradation is determined by the accumulation of sustain pulses in the selectively operated subframe each having a different number of sustain pulses by assigning different times of duration to subframes of a single frame.

On the other hand, several theoretical methods have been proposed to implement the above-described image implementation at high speed, and one of them is the theory of realizing an image by dividing a screen. 2 is a waveform diagram illustrating waveforms supplied to each electrode in a screen division method. Referring to this, the screen is driven by dividing the screen into a total of eight blocks in a subframe method, and is supplied to blocks 1, 2, 3, 4 and blocks 5, 6, 7, 8 which are upper blocks of the eight blocks. The waveform is the same but the phase (PHASE) shifted waveform is used as the driving waveform. This has the effect that the driving method of the upper block is applied to the lower block as it is to drive the upper and lower blocks driven separately from each other by using one driving pulse.

However, as shown in Fig. 3 showing the luminance implementation of the entire screen, the erase operation is necessary to invalidate the previously discharged before the write operation, and since the occurrence of the write operation and the erase operation is very irregular, the implementation of the driving circuit is very complicated. There was a problem done.

The present invention is conceived for the simplification of a driving device that controls irregular write and erase operations that occur when driving a screen by dividing the screen into a total of eight blocks in the subframe for high speed implementation of the conventional screen. In particular, the Y sustain electrode driving IC to be controlled by the main controller and a memory unit storing information on the display line are mounted outside the control unit in a screen division method, thereby providing a driving device of the plasma display panel with a simple configuration of the control unit. Its purpose is to.

1 is a diagram illustrating a luminance implementation of one frame;

2 is a waveform diagram showing waveforms supplied to each electrode in the screen division driving method;

3 is a diagram illustrating a luminance implementation of a full screen;

4 is a configuration diagram schematically illustrating a connection of a blocked 640 × 480 screen according to an embodiment of the present invention, and a connection of a driving device to which a driving pulse is applied thereto;

5 is a diagram illustrating a connection configuration between an input terminal and an output terminal of Y sustain electrode driving ICs;

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

400: main control part 401: writing motion

402: elimination action epirome 410: first Y sustain electrode driver

411 to 418 and 421 to 428 Y sustain electrode driving ICs

420: second Y sustain electrode driver 430: first X sustain electrode driver

431: Second X sustain electrode driver 440: First Z sustain electrode driver

450: second Z sustain electrode driver

The present invention for achieving the above object is, N Y and Z sustain electrodes arranged alternately in parallel one by one, and M arranged in parallel to each other so as to be orthogonal with a predetermined space between the Y and Z sustain electrodes Main control unit for generating a control signal according to the image data to control a three-electrode plasma display panel composed of M x N cells having a matrix form by means of X sustain electrodes, and a driving unit for receiving control signals from the control unit. A memory unit stores information on selection, a Y sustain electrode driver for applying a driving waveform based on control signals of the main controller and information stored in the memory unit, an X sustain electrode driver, and a Z sustain electrode driver. The screen is driven by dividing it into eight blocks, but separate X, Y and Z sustain electrode driving parts are provided in the upper four blocks and the lower four blocks, respectively. In comparison, the driving waveforms applied to the upper blocks and the lower blocks from the driving units are the same and the phase of the plasma display panel is shifted by a predetermined angle. First Y sustain electrode sub-drive parts connected to the Y sustain electrode in one-to-one correspondence, and second Y sustain electrode sub connected to the Y sustain electrode in the horizontal display line included in the lower blocks in one-to-one correspondence. The first Z sustain electrode driver connected to the driving units, the Z sustain electrode connected to the horizontal display lines included in the upper blocks, and the Z sustain electrode connected to the horizontal display lines included in the lower blocks. The output lines are connected to the second Z sustain electrode driver connected to the output lines in common, and to the X sustain electrodes of the vertical display lines included in the upper blocks. One corresponding to claim 1 connected to X and the sustain electrode driver, and the output lines to claim 2 X sustain electrode driver is connected to one-to-one correspondence with the sustain electrodes X of the vertical display lines that are included in the sub-block; A memory unit which is located outside the main control unit and whose contents are read by the main control unit at every sustain discharge step; The main controller may be provided with a main control unit for reading out the contents of the memory unit and outputting a control signal for discharging a cell according to the contents.

In addition, according to an embodiment of the present invention, a control line connected to the Y sustain electrode sub-drive parts from the main control part is commonly used in the scanning of the plasma display panel, and Y from the main control part. The data line connected to the sustain electrode sub-drivers is connected to each of the Y sustain electrode sub-drivers.

In addition, the memory unit is composed of an EPROM, and one word of data stored in the EPROM is 8 bits, and is read out by two words in the reading process, and the upper part of each word of data stored in the EPROM is read. (MSB) Three bits are information on selection of each Y sustain electrode sub-driver, and the lower five bits are information on selection of a horizontal display line to be scanned.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

Fig. 4 is a block diagram schematically illustrating the connection of a 640 × 480 screen blocked by the present invention and a drive device for applying a drive pulse thereto. Referring to this, a total of 480 Y and Z sustain electrodes alternately arranged in parallel with each other and 640 X sustain electrodes arranged in parallel with each other so as to be orthogonal to each other with a predetermined space therebetween. The main word that issues a control signal to each driver according to the image data in order to divide the screen of the three-electrode plasma display panel composed of 640 × 480 cells in matrix form into 8 blocks, and divide the screen into two blocks. Wealth 400; An epirome 401 including information on selection of a drive unit related to a write operation; A first Y sustain electrode driver 410 for applying a driving voltage to the Y sustain electrodes Y1 to Y240 included in an upper block by a control signal of the main controller 400 and ROM information stored in the pyrom 401; ; A second Y sustain electrode driver 420 for applying a driving voltage to the Y sustain electrodes included in the lower blocks Y241 to Y480; A first X sustain electrode driver 430 for applying a driving voltage to the X sustain electrode included in the upper block; A second X sustain electrode driver 431 for applying a driving voltage to the X sustain electrodes included in the lower blocks Y241 to Y480; A first Z sustain electrode driver 440 connected to the Z sustain electrodes included in the upper blocks Z1 to Z240 to apply a driving voltage; A second Z sustain electrode driver 441 is connected to the Z sustain electrodes included in the lower blocks Z241 to Z480 to apply a driving voltage.

In this case, the first Y sustain electrode driver 410 and the second Y sustain electrode driver 420 are Y sustain electrode driver ICs 411 to 418 in which output lines are connected in one-to-one correspondence to the Y sustain electrodes of each horizontal display line. , 421 to 428, output lines of the first Z sustain electrode driver 440 are commonly connected to a Z sustain electrode included in an upper block, and output lines of the second Z sustain electrode driver 441 are respectively. Commonly connected to the Z sustain electrode included in the lower block.

Output lines of the first X sustain electrode driver 430 are connected to the X sustain electrodes included in the upper block in a one-to-one correspondence, and output lines of the second X sustain electrode driver 431 are in the lower block. Output lines are connected in a one-to-one correspondence to the included X sustain electrodes.

5 is a diagram illustrating a connection configuration of an input terminal and an output terminal of the Y sustain electrode driving ICs. As shown, a control line connected to the Y sustain electrode driving ICs 501, 502, 503... Is commonly used, and a data line connected to the Y sustain electrode driving ICs 501, 502, 503. Are connected to the drive ICs 501, 502, 503, respectively.

In order to divide the entire 480 lines into eight blocks, 60 blocks are included in one block and two 30-pin output Y sustain electrode driver ICs are used in one block.

In addition, one word of data stored in the pyramid is 8 bits, upper 3 bits are Y sustain electrode driver IC selection information, and lower 5 bits are horizontal display line selection information to be scanned.

In addition, ROMs 451, 452 and 453 having information on driving waveforms to be supplied to the X, Y and Z sustain electrodes are mounted outside the main controller, and are connected to the main controller, the data line and the address line.

Operation of the driving apparatus of the plasma display panel configured as described above is as follows.

The entire screen is driven by dividing it into eight blocks, and the driving waveforms applied to the upper four blocks (blocks 1 to 4) and the lower four blocks (blocks 5 to 8) are vertically symmetrical with each other. The concept is that the driving method of the top four blocks is applied to the bottom four blocks as it is, but the waveform itself must be shifted.

If you refresh the screen at 60Hz, it takes 16.67mS (1 / 60Hz) to rewrite one frame. During 16.67mS, each block is properly arranged so as not to overlap bits 8, 7, ..., 2, 1. At this time, the write pulse is at least 2 at the sustain time. μ To S and the erase pulse time is at least 0.7 μ To be

In addition, current driving ICs generally have 30 to 40 output pins, and the operating frequency of the high-voltage FET (FIELD EFFECT TRANSISTOR) (not shown), which is the final output terminal of data, does not exceed 20 MHz. It is used as the pin output, and the operation of the FET is used at 10MHz. Due to the above limitation, a 30 clock shift operation is required when data is loaded into the driving IC in one sustain time.

At this time, if four write pulses are put in one holding time, approximately 12 μ S (3 μ S × 4), which takes a lot of time. For this method, the shifted sustain waveform is used as shown in FIG. 2, and the period is 12,8. μ Set to S and use.

For the data required for the write operation, (drive IC 0, line 1) (drive IC 2, line 1) is selected from the upper blocks (blocks 1 to 4) at the first sustain discharge. Then (Drive IC 0, Line 2) (Drive IC 2, Line 2) is selected. And (Drive IC 0, Line 3) (Drive IC 2, Line 3), (Drive IC 0, Line 1) (Drive IC 2, Line 1). Is in order. After 30 lines, (Drive IC 1, Line 1) (Drive IC 3, Line 1), (Drive IC 1, Line 2) (Drive IC 3, Line 2), (Drive IC 1, Line 3) (Drive IC 3 , Line 3...).

In order to simplify and easily implement the data output, as shown in Table 1, the selection order of the Y sustain electrode driving IC is stored in the pyramid 401, and two of them are selected for each sustain discharge (Select 1, Select 2, The main control section determines which Y sustain electrode driving IC is driven.

Ipirom's contents MSB LSB 123456 ... 0 0 0 0 0 0 0 10 1 0 0 0 0 0 10 0 0 0 0 0 1 00 1 0 0 0 0 1 00 0 0 0 0 0 1 10 1 0 0 0 0 1 1 ... Choice 1 Choice 1 Choice 2 Choice 2 Choice 3 Choice 3

The upper (MSB) three bits of the ROM data shown in Table 1 above are information on selecting the Y sustain electrode driving IC, and the lower five bits are information about line selection from line 1 to line 30.

In the erasing operation, the memory unit of this pyrom 402 is separately provided in the same manner as the method used in the writing operation, so that information on selection of a driving IC to be driven in every erase operation and information for selecting a line connected to the selected driving IC are provided. After storing the erase operation using the information.

According to the present invention, in the screen division method, the Y sustain electrode driving IC to be controlled by the main controller and the memory unit storing the information on the display line are mounted outside the controller, thereby simplifying the configuration of the controller and facilitating driving. have.

Claims (5)

The entire screen is formed in a matrix by N Y and Z sustain electrodes arranged in parallel with each other alternately and M X sustain electrodes arranged in parallel so as to be orthogonal to each other with a predetermined space therebetween. A main controller unit for generating a control signal according to image data to control a three-electrode plasma display panel including M × N cells of the N-cell, and a memory unit for storing information on selection of a driver unit to receive the control signal from the controller; And a Y sustain electrode driver for applying a driving waveform based on the control signal of the main controller and information stored in the memory unit, an X sustain electrode driver, and a Z sustain electrode driver to drive the entire screen into eight blocks. The driving unit includes separate X, Y, and Z sustain electrode driving units in the upper four blocks and the lower four blocks from the driving units, respectively. In the driving apparatus of the plasma display panel in which the driving waveforms applied to the upper blocks and the lower blocks are equal to each other, and their phases are shifted by a predetermined angle, the Y holding of the horizontal display line included in the upper blocks is maintained. First Y sustain electrode sub-drivers connected to the electrodes in one-to-one correspondence, and second Y sustain electrode sub-drives connected in one-to-one correspondence to the Y sustain electrodes of the horizontal display lines included in the lower blocks. And a first Z sustain electrode driver having an output line commonly connected to a Z sustain electrode connected to the horizontal display lines included in the upper blocks, and an output line to the Z sustain electrode connected to the horizontal display lines included in the lower blocks. The second Z sustain electrode driver connected in common and the output lines are connected in a one-to-one correspondence to the X sustain electrodes of the vertical display lines included in the upper blocks. A first X sustain electrode driver and a second X sustain electrode driver connected to the X sustain electrodes of the vertical display lines included in the lower blocks in a one-to-one correspondence; A memory unit which is located outside the main control unit and whose contents are read by the main control unit at every sustain discharge step; And a main control unit for reading out the contents of the memory unit and outputting a control signal for discharging a cell in accordance with the contents of the memory unit. The method of claim 1, In the scanning of the plasma display panel, a control line connected to the Y sustain electrode sub-drive parts from the main control part is commonly used, and a data line connected to the Y sustain electrode sub-drive part from the main control part is used for each Y sustain electrode. A driving apparatus of the plasma display panel, characterized in that each connected to the sub-drive. The method of claim 1, And the memory unit is composed of EPROM. The method of claim 3, wherein And one word of data stored in the pyrom is 8 bits, and is read out by two words in the reading process. The method of claim 3, wherein The upper (MSB) 3 bits of each word of the data stored in the YPIROM are information regarding the selection of each Y sustain electrode sub-driver, and the lower 5 bits are information about the selection of the horizontal display line to be scanned. Drive of display panel

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