KR20060096690A - Method of decreasing flicker for plasma display panels - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of reducing flicker in a plasma display panel. When the number of sustains required for frame processing is changed according to the change in external temperature, the present invention is progressive over several frames until the target number of targets is reached. In this case, the flicker caused by the sudden change in the number of sustains can be reduced and the image quality can be improved.

PDP, Frame, sustain, Temperature, Flicker

Description

Flicker reduction method in plasma display panel {Method of decreasing flicker for Plasma Display Panels}

1 is an overview of a frame driving method in a PDP;

2 is an example for explaining the variation in the number of sustains according to the temperature change,

3 is an example for explaining a variation in the number of sustains of a frame according to a temperature change;

4 is a flow chart of one embodiment according to the present invention;

5 is an outline for a detailed description of the embodiment,

6 is a flow chart of another embodiment according to the present invention;

7 is an outline for a detailed description of the another embodiment.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of reducing flicker in a plasma display panel, and in particular, a change in the number of sustains due to a temperature change in a plasma display panel (PDP) can be made gradually, which occurs when the number of sustains changes rapidly. A method of reducing flicker is provided.

Referring to FIG. 1, a plasma display panel (hereinafter referred to as a PDP) is driven by dividing a frame into several subfields having different emission counts in order to realize gray scale of an image. Doing.

Each subfield SF1 to SF8 is divided into an address section for selecting a discharge cell and a sustain section for implementing gray scale according to the number of discharges. Which cell on the entire screen the light is to be emitted for the frame to be displayed is determined in the address section, and in the sustain section, the number of sustains is adjusted according to the desired brightness.

On the other hand, the PDP varies the length of the address section and the number of sustains in accordance with the temperature in every subfield SF1 to SF8 in order to improve discharge characteristics as the external temperature changes. That is, when the external temperature increases, the length of the address section is reduced and the number of sustain increases. When the external temperature decreases, the length of the address section is increased and the number of sustain is decreased.

Referring to FIG. 2, an example of displaying an external temperature in 3 bits may be expressed as the highest temperature as '111' and the lowest temperature as '000', and the number of sustains for each temperature is the highest temperature. It gradually decreases as the temperature decreases from time to time. Although FIG. 2 has been described as an example for one subfield SF1, the number of sustained units for each temperature is set for all subfields.

The change in the number of sustains due to the change of the external temperature is reflected every frame. FIG. 3 shows the external temperature applied to each frame and the number of sustains according to each frame. Each frame is processed according to the vsync signal. At this time, when the external temperature is maintained at '001' and then changed to '010', the number of sustains is changed from 20 to 30. Such a sudden change in the number of sustains may cause flicker, which is a flicker of the screen.

That is, in the related art, the number of sustains is changed according to the change of temperature, but the number of sustains is changed rapidly according to the change of the external temperature, thereby causing a flicker.

Therefore, the present invention has been made to solve the above problems, a method that can reduce the flicker by gradually changing the amount of light emitted by varying the number of sustain in accordance with the change in the external temperature The purpose is to provide.

In order to achieve the above object, the flicker reduction method of the plasma display panel according to the present invention comprises the steps of setting a sustain number (target sustain number) corresponding to the changed temperature when the external temperature is changed. ; Starting to count the number of frames; And processing each frame by increasing the sustain number of the current frame by a predetermined increment until the target sustain number is reached using the counted frame number.

The number of frames to be processed may be limited to a certain number while increasing the number of sustains by a predetermined increment. In this case, when the limited number of frames is reached before the number of target sustains is reached, the current number of sustains may be immediately set to the number of target sustains.

In addition, in order to prevent the number of sustain from changing again due to the change of the external temperature during the gradual fluctuation of the target sustain number, the average temperature may be used as the external temperature.

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

Referring to FIG. 4, when the external temperature changes, the number of sustains (target sustain number) corresponding to the changed external temperature is set (S41 and S42). The method for setting the number of target sustains in step S42 can be configured in various ways. An example of the target sustain number is set with reference to a table as shown in FIG.

The number of frames to be processed is now counted (S43).

When the current sustain number is smaller than the target sustain number by comparing the current sustain number with the target sustain number (S44), a predetermined increment D is added to the current sustain number (S45).

The current sustain number when the step S44 is performed is the sustain number at the temperature immediately before the external temperature is changed, and the sustain number is gradually added through the following process. Incremental D can also be set to any value (e.g., 1) that can effectively reduce flicker.

In step S45, the current frame is processed using the current sustain number to which the increment D is added (S46), the frame count is increased by one, and the flow proceeds to step S44 (S47).

In addition, when the external temperature does not fluctuate (S41) or when the current sustain number reaches the target sustain number as a result of the determination in step S44, the current sustain number is maintained until the temperature change occurs again. The frame is processed (S48).

Meanwhile, as in steps S44 to S47, the number of frames to which the process of gradually increasing the current sustain number is applied may be limited to a certain number.

Referring to FIG. 5, when the external temperature changes from '001' to '010', assuming that the number of sustains (target sustain number) is 30 at the temperature '010', the number of sustains in the first frame after the external temperature changes Instead of converting to 30 immediately, it is gradually changed over several frames to finally 30.

That is, the number of frames to be processed starts counting when the external temperature is changed from '001' to '010'. In this case, if the number of frames to which the process of gradually increasing the current sustain number is applied is limited to 60, the number of frames is counted up to 60 only.

In addition, assuming that the increment D of the current sustain number to be gradually increased is set to 1, the current sustain number increases by 1 each time a frame is processed from the 20 sustain numbers for the temperature '001' just before the change. Therefore, when the tenth frame is processed, the target target number, which is the final target value, is reached. Now that the target sustain number has been reached, the target sustain number 30 is maintained until the 60th frame is reached.

In addition, although the number of target sustains to be fluctuated according to the temperature change is very large, the number of target sustains may not be reached even though the current sustain number is increased up to a preset frame number. In this case, after counting the predetermined number of frames, the current sustain number may be forcibly changed to the target sustain number.

Referring to FIG. 6, when the external temperature changes, the number of sustain (target sustain number) corresponding to the changed external temperature is set (S61 and S62).

Then, the number of frames to be processed is started (S63).

Now, when the current sustain number is smaller than the target sustain number by comparing the current sustain number with the target sustain number (S64), it is determined whether the number of frames counted up to the present reaches the target frame number (S65).

The current sustain number when the step S64 is performed is the sustain number at the temperature just before the external temperature is changed, and the sustain number is gradually added through the following process. Incremental D can also be set to any value (e.g., 1) that can effectively reduce flicker.

As a result of the determination in step S65, when the number of frames counted so far does not reach the target frame number, a predetermined increment D is added to the current number of sustains (S66-1). In step S66-1, the current frame is processed using the current sustain number to which the increment D is added (S66-2), the frame count is increased by one, and the flow proceeds to step S64 (S66-3).

In addition, when the external temperature is not changed (S61) or when the current sustain number reaches the target sustain number as a result of the determination in step S64, the current sustain number is maintained until the temperature change occurs again. The corresponding frame is processed (S68).

However, when it is determined in step S65 that the number of frames counted up to the present reaches the limited number of target frames, the current sustain number is immediately converted to the target sustain number (S67), and the frame is processed using the current sustain number (S68). ).

This will be described in detail with reference to FIG. 7.

The external temperature changed from '000' to '111', the number of sustains at temperature '000' is 10, the number of sustains at the temperature '111' (target sustain number) is 80 and the number of frames is limited to 60. Assume that

Then, the number of frames to be processed starts counting when the external temperature is changed from '000' to '111'. At this time, since the number of frames to which the process of gradually increasing the current sustain number is applied is limited to 60, the number of frames is counted up to 60 only.

In addition, assuming that the increment D of the current sustain number to be gradually increased is set to 1, the current sustain number increases by 1 each time a frame is processed from the 10 sustain numbers for the temperature '000' immediately before the change. Therefore, when the 60th frame is processed, the current number of sustains at that time is 70.

That is, although the limited number of frames is all counted, the current sustain number does not reach the target target number, which is the final target value. In this case, the current sustain number is forcibly changed to the target target number (ie, 80) as the final target value.

As in each of the embodiments described above, when the external temperature changes, the number of target sustains is determined, and the number of current sustains is gradually changed to the number of target sustains. In this case, the average temperature may be used instead of the instantaneous temperature as the input temperature in order to prevent the change in the number of sustained by the external temperature before reaching the final target sustain number.

The present invention is not limited to the above-described embodiments and can be variously modified and implemented by those skilled in the art without departing from the technical spirit of the present invention.

According to the present invention, when the external temperature of the PDP is changed, the number of sustains is gradually changed without changing the number of sustains according to the temperature change so that the amount of light emitted is gradually changed to reduce flicker and improve image quality.

Claims (4)

Setting a sustain number (target sustain number) corresponding to the changed temperature when the external temperature is changed; Starting to count the number of frames; And And processing each frame by increasing the number of sustains of the current frame by a predetermined increment until the target number of sustains is reached using the counted number of frames. The method of claim 1, The number of frames to be processed while increasing the number of sustains by a predetermined increment is configured to be limited to a certain number of flicker reduction method in a plasma display panel. The method of claim 2, And if the limited number of frames is reached before the number of target sustains is reached, the current number of sustains is set immediately to the number of target sustains. The method according to any one of claims 1 to 3, And the external temperature is configured to use an average temperature.

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