KR100366103B1 - A method for driving separately sustain pulse of plasma display panel - Google Patents

Abstract

The present invention relates to an apparatus for driving a plasma display panel, and more particularly, to an apparatus for driving an individual sustain discharge of a plasma display panel for removing a sustain discharge pulse applied thereto when there is no cell performing a real discharge in a corresponding line of a scan electrode. will be. The sustain discharge individual driving apparatus of the plasma display panel generates a drive control signal of address, X, and Y electrode lines according to an image signal from the outside, and applies Y common so that a sustain discharge pulse is applied only to the Y electrode line performing the actual discharge. A control unit for generating a driving control signal, an address driver for processing an address signal among the driving control signals from the control unit and applying the address signal to the address electrode lines, and an X electrode line by the X driving control signal among the driving control signals from the control unit X driving unit for driving the driving unit, a scan driving unit driving the Y scan electrode line by the Y driving control signal among the driving control signals from the control unit, and real discharge of the Y scanning line by the Y common driving control signal from the control unit Only sustain pulses in the Y scan line to perform It includes the Y common driver to apply. According to the present invention, when there is no cell that performs actual discharge in each scan electrode corresponding line when driving the plasma display panel, an unnecessary power applied to the unnecessary power is suppressed by removing the sustain discharge pulse applied thereto, and the region does not emit light. Since no pulses are applied to the circuit, erroneous discharge does not occur in this section even if excessive movement of space charge occurs.

Description

Individual discharge device for sustaining discharge of plasma display panel {A method for driving separately sustain pulse of plasma display panel}

The present invention relates to an apparatus for driving a plasma display panel, and more particularly, to an apparatus for driving an individual sustain discharge of a plasma display panel for removing a sustain discharge pulse applied thereto when there is no cell performing a real discharge in a corresponding line of a scan electrode. will be.

1 shows a structure of a conventional three-electrode surface discharge plasma display panel. 2 illustrates a pattern of electrode lines of the plasma display panel of FIG. 1. 3 shows one discharge cell of the panel of FIG. 1. Referring to the drawings, between the front and rear glass substrates 10 and 13 of the general surface discharge plasma display panel 1, the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Rm , a dielectric layer (11,15), Y electrode lines (Y ₁ , ..., Y _n ), X electrode lines (X ₁ , ..., X _n ), fluorescent layer 16, partition wall 17 and magnesium monoxide as protective layer (MgO) layer 12 is provided.

The address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Rm are formed in a predetermined pattern on the front surface of the rear glass substrate 13. The lower dielectric layer 15 is formed in front of the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Rm . The barrier ribs 17 are formed on the front surface of the lower dielectric layer 15 in a direction parallel to the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Rm . The partition walls 17 function to partition the discharge region of each discharge cell and to prevent optical talk between the discharge cells. The fluorescent layer 16 is formed between the partition walls 17.

The X electrode lines (X ₁ ,..., X _n ) and the Y electrode lines (Y ₁ ,..., Y _n ) are orthogonal to the address electrode lines (A _R1 , A _G1 ,…, A _Gm , A _Rm ). The rear surface of the front glass substrate 10 is formed in a predetermined pattern. Each intersection defines a corresponding discharge cell. Each X electrode line (X ₁ ,..., X _n ) and each Y electrode line (Y ₁ ,..., Y _n ) are indium tin oxide (ITO) electrode lines (X _na , Y _na of FIG. 3) of a transparent conductive material. And a bus electrode line (X _nb , Y _nb of FIG. 3) made of metal are combined. The upper dielectric layer 11 is formed after the X electrode lines X ₁ ,..., X _n and the Y electrode lines Y ₁ ,..., Y _n . A magnesium monoxide (MgO) layer 12 for protecting the panel 1 from a strong electric field is formed by applying the entire surface to the back surface of the upper dielectric layer 11. The plasma forming gas is sealed in the discharge space 14.

The driving method basically applied to the plasma display panel is a method in which reset, address, and sustain discharge steps are sequentially performed in a unit subfield. In the reset step, the residual wall charges in the previous subfield are erased and driven so that the space charges are generated evenly. In the address step, the wall charges are driven to be formed in the selected discharge cells. In the sustain discharge step, light is driven in the discharge cells in which the wall charges are formed in the addressing discharge step. That is, when alternately applying a pulse of a relatively high voltage to all the X electrode lines (X ₁ ,..., X _n ) and the Y electrode lines (Y ₁ ,..., Y _n ), discharge cells in which wall charges are formed Causes surface discharge. At this time, a plasma is formed in the gas layer, and the fluorescent layer 16 is excited by the ultraviolet radiation to generate light.

In the above-described driving method, a time division driving apparatus for dividing a frame which is a unit display period into subfields of different display times to perform gray scale display in order to perform gray scale display on a plasma display panel is applied. . A case in which eight subfields are set per unit frame in order to perform 256 (2 ⁸ ) gray scale display using 8-bit image data will be described below.

Referring to FIG. 4, the unit frame is divided into eight subfields SF1,..., SF8 to explain the time division gray scale display. Further, each subfield SF1, ..., SF8 is divided into address periods A1, ..., A8 and sustain discharge periods S1, ..., S8.

In each address period A1, ..., A8, a display data signal is applied to the address electrode lines (A _R1 , A _G1 , ..., A _Gm , A _{Rm in} FIG. 1) and at the same time, each Y electrode line Y ₁ ,. , Y _n ), are sequentially applied. Accordingly, when a high level display data signal is applied while the scan pulse is applied, wall charges are formed by the address discharge in the corresponding discharge cell, and wall charges are not formed in the discharge cell that is not.

In each sustain discharge period S1, ..., S8, sustain discharge pulses are alternately applied to all X electrode lines X ₁ , ..., X _n and Y electrode lines Y ₁ , ..., Y _n . This causes display discharge in discharge cells in which wall charges are formed in corresponding address periods A1, ..., A8. Therefore, the luminance of the plasma display panel is proportional to the length of the sustain discharge periods S1, ..., S8 occupied in the unit frame. The lengths of the sustain discharge cycles S1, ..., S8 occupy a unit frame are 255T (T is the unit time). Therefore, it can be displayed in 256 gray scales, even if it is not displayed once in a unit frame.

As shown in FIG. 5, the driving apparatus of the general plasma display panel 1 includes a controller 52, an address driver 53, an X driver 54, and a Y driver 55. The controller 2 generates driving control signals S _A , S _Y , and S _X according to an image signal from the outside. The address driver 53 generates the display data signal by processing the address signal S _A among the driving control signals S _A , S _Y , and S _X from the controller 52, and generates the display data signal. Applied to the electrode lines. The X driver 54 processes the X driving control signal S _X from the driving control signals S _A , S _Y , and S _X from the controller 52 and applies the X driving control signal S _X to the X electrode lines.

The Y driver 55 processes the Y driving control signal S _Y among the driving control signals S _A , S _Y , and S _X from the controller 52 and applies the Y driving control signal S _Y to the Y electrode lines. The Y driver 55 may be divided into a scan driver 551 and a Y-common driver 552. The scan driver 551 outputs the drive signal only for the address period, and the Y-common driver 552 outputs the drive signal only for the display discharge period.

FIG. 6 is a view for explaining a sustain discharge driving apparatus of a conventional plasma display panel. The scan driver 551 and the Y-common driver 552 of the Y driver 55 use a conventional FET internal diode. Instead, the switching regions of the FETs 55-11, 55-12, ..., 55-n1, 55-n2 can be used. That is, the scan driver 551 transmits the driving signals to the H-side FETs 55-11, 55-21, ... 55-n1 and the L-side 55-12, 55-22, ... 55- in the address period. n2) sequentially, and the Y-common driver 552 sequentially transmits a sustain discharge pulse to the L-side FETs 55-12, 55-22, ... 55-n2 corresponding to each scan line in the sustain discharge cycle. In this case, the sustain discharge pulse is applied to all panels in the same state and power is recovered. The solid line shown in FIG. 6 is the current direction when the sustain discharge pulse is applied, and the dotted line is the current direction when the energy recovery sink is performed.

As described above, even when there is no cell to perform the actual discharge in the scan electrode line, the sustain discharge pulse is applied and unnecessary power is wasted, thereby causing an error in the discharge.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an individual sustain discharge driving apparatus for a plasma display panel which removes a sustain discharge pulse applied thereto when no cell performs a real discharge on a corresponding line of a scan electrode.

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

FIG. 2 is an electrode line pattern diagram of the plasma display panel of FIG. 1.

3 is a cross-sectional view illustrating one discharge cell of the plasma display panel of FIG. 1.

FIG. 4 is a general driving timing diagram for Y electrode lines of the plasma display panel of FIG. 1.

5 is a block diagram showing the configuration of the plasma display panel driving apparatus.

6 is a view for explaining a sustain discharge driving apparatus of a conventional plasma display panel.

7 is a view for explaining a sustain discharge individual driving apparatus of the plasma display panel according to the present invention.

FIG. 8 is a diagram showing a line to which the sustain discharge pulses of FIG. 7 are individually applied when an image is displayed.

The sustain discharge individual driving device of the plasma display panel for solving the technical problem to be achieved by the present invention generates the drive control signal of the address, X, Y electrode lines in accordance with the image signal from the outside, and performs the actual discharge A controller for generating a Y common drive control signal such that a sustain discharge pulse is applied only to the Y electrode line; An address driver which processes an address signal among the driving control signals from the controller and applies the address signal to the address electrode lines; An X driver for driving X electrode lines by an X driving control signal among the driving control signals from the controller; A scan driver for driving the Y scan electrode line according to a Y drive control signal among the drive control signals from the controller; And a Y common driver for applying a sustain discharge pulse only to the Y scan line that performs real discharge among the Y scan lines by a Y common drive control signal from the controller. A control unit which generates a drive control signal of the address and X electrode lines and generates a drive control signal such that a sustain discharge pulse is applied only to the Y electrode line performing actual discharge; An address driver which processes an address signal among the driving control signals from the controller and applies the address signal to the address electrode lines; An X driver for driving X electrode lines by an X driving control signal among the driving control signals from the controller; A scan driver for driving the Y scan electrode lines according to a Y drive control signal among the drive control signals from the controller; And a Y common driver configured to selectively apply a sustain discharge pulse to the Y scan line by a Y drive control signal among the drive control signals from the controller.

In this case, the control unit outputs a Y driving control signal for controlling the Y common driving unit so that a sustain discharge pulse is applied only to the Y scan line performing the actual discharge.

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

7 is a view for explaining a sustain discharge individual driving apparatus of the plasma display panel according to the present invention. FIG. 8 is a diagram showing a line to which the sustain discharge pulses of FIG. 7 are individually applied when an image is displayed.

Next, the present invention will be described in detail with reference to FIGS. 5, 7 and 8.

5, 7 and 8, the individual sustain discharge driving apparatus of the plasma display panel according to the present invention includes a plasma display panel 1, a controller 52, an address driver 53, an X driver 54, A Y driver 55 is included, and the Y driver 55 includes a scan driver 551 and a Y common driver 552.

The controller 52 generates driving control signals S _A , S _Y , and S _X according to an image signal from the outside. That is, the controller 52 processes the image data input from the outside to generate scan data, sustain discharge data, display data signal, and common data signal. The address driver 53 processes the address signal S _A among the drive control signals from the controller 52 and displays the resulting display data signal in the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Rm ). The X common driver 54 generates a drive signal to be applied to the X common electrode lines X ₁ ,..., X _n by the X drive control signal S _X among the drive control signals from the controller 52. Let's do it.

The scan driver 551 generates driving signals to be applied to the scan electrode line by the Y driving control signal S _Y among the driving control signals from the controller 52. The Y common driver 552 generates a driving signal to be applied to the Y common electrode lines by the Y driving control signal S _Y among the driving control signals from the controller 52. In this case, the scan driver 551 outputs a scan driving signal according to a predetermined scan order in an address period for forming wall charges in the pixel area to be selected, and the Y common driver 552 is configured to generate light in the selected pixel area. The sustain discharge drive signal is output in accordance with the sustain discharge data corresponding to the sustain discharge cycle.

The scan driver 551 and the Y-common driver 552 of the Y driver 55 make it possible to use the switching regions of the FETs 55-11, 55-12, ..., 55-n1, 55-n2, thereby scanning The driver 551 transmits the drive signal to each of the H-side FETs 55-11, 55-21, ... 55-n1 and the L-side 55-12, 55-22, ... 55-n2 in the address period. By sequentially switching, scan driving signals are applied to the scan lines. The Y common driver 552 switches the sustain discharge pulses to the H-side FETs 55-12, 55-22, ... 55-n2 corresponding to the lines for displaying a real image among the scan lines in the sustain discharge cycle. Light is generated in the pixel region.

At this time, the controller 52 determines whether the actual image display effective discharge exists in the corresponding scan line and operates to control the Y driving signal. If there is no On signal of each subfield applied to each corresponding scan line, discharge does not occur, so the output terminal of the line is turned off and no sustain discharge pulse is applied.

On the other hand, in the driving device of the plasma display panel with high driving power consumption, a power regeneration circuit must be provided. Such a power regeneration circuit is provided in the Y common floating portion 552 and the X driver 54. That is, in the Y common driver 552 and the X driver 34, in the sustain discharge cycle, the sustain discharge pulse is applied to the X electrode lines X ₁ ,..., X _n and the Y electrode lines Y ₁ ,. When periodically applied to Y _n ), unnecessary power is recovered to discharge-cells displayed in the current pulse period and applied to discharge-cells to be displayed in the next pulse period. Unnecessary power is recovered by the L-side FETs 55-12, 55-22, ..., 55-2n connected to each scan line.

In FIG. 7, the solid line drawn in bold is the current direction at the time of applying the sustain discharge pulse, and the dotted line is the current direction at the time of energy recovery. Compared with FIG. 6, it can be seen that the current direction is opposite to that of the conventional art.

FIG. 8 is a diagram showing a line to which a sustain discharge pulse is applied and a line to which no sustain discharge pulse is applied when an image like the figure is displayed for only one subfield. In the line marked on the scan electrode line, the pulse is applied because the FET is turned on, but there is no unnecessary pulse because no pulse is applied in the other region.

Using the same FET switching method of the present invention for the common electrode can further reduce power consumption.

The present invention is not limited to the above-described embodiments and can be modified by those skilled in the art within the spirit of the invention.

As described above, according to the present invention, when there is no cell performing actual discharge in each scan electrode corresponding line when driving the plasma display panel, the reactive power applied to the unnecessary power is suppressed by removing the sustain discharge pulse applied thereto. Since no pulse is applied to the region that does not emit light, there is an effect that no mis-discharge occurs in this section even if excessive movement of space charge occurs.

Claims (2)

In the plasma display panel drive device, A control unit for generating drive control signals of address, X, and Y electrode lines according to an image signal from the outside, and generating a Y common drive control signal so that a sustain discharge pulse is applied only to the Y electrode line for performing actual discharge; An address driver which processes an address signal among the driving control signals from the controller and applies the address signal to the address electrode lines; An X driver for driving X electrode lines by an X driving control signal among the driving control signals from the controller; A scan driver for driving the Y scan electrode line according to a Y drive control signal among the drive control signals from the controller; And And a Y common driver for applying a sustain discharge pulse only to the Y scan line that performs real discharge among the Y scan lines by a Y common drive control signal from the controller. delete