FR2817438A1 - Plasma display panel illumination method having elementary cells with images sub sweeps formed using intermediate/main images movement compensated and period displayed scan period lower. - Google Patents

Abstract

The video image display has a number of elementary cells with the image formed using sub sweeps during which elementary cells may be illuminated or extinct. A sequence of principle images (I-1,I) are formed with intermediate images formed from the main images and compensated for movement. The sequence of images from the principal and intermediate images are displayed over a time period lower than the scan period.

Description

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METHOD FOR DISPLAYING VIDEO IMAGES ON PLASMA DISPLAY PANEL AND PLASMA DISPLAY PANEL
The present invention relates to a method for displaying video images on a plasma display panel. The invention finds more particularly its application in plasma display panels (PAP) comprising an array of elementary cells which can take either an on state or an off state.

PAP technology makes it possible to obtain flat and large display screens. The PAP generally comprise two insulating slabs delimiting between them a space filled with gas in which are defined elementary spaces delimited by barriers. Each slab is provided with one or more networks of electrodes. An elementary cell corresponds to an elementary space provided on either side of said elementary space with at least one electrode. To activate an elementary cell, an electrical discharge is caused in the corresponding elementary space by applying a voltage between the electrodes of the cell. The electric discharge then causes an emission of UV rays in the elementary cell. Luminophores deposited on the cell walls transform UV into visible light.

The operating period of an elementary cell of a PAP corresponds to the display period of a

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 video image. The latter has a duration T. Each display period is made up of elementary periods commonly called sub-scans. Each underscan has a cell addressing period and a holding period. The addressing period consists in sending or not an electrical pulse to the elementary cell depending on whether the latter must be positioned in an on or off state. The holding period consists in sending a succession of pulses for a given period of time to keep the cell in an on or off state. The periods of maintenance correspond to the periods of illumination of the cell. The gray level obtained for the cell is then a function of the number of holding pulses received by the latter.

The distribution of the addressing periods and of the holding periods for a given elementary cell for displaying an image is shown in FIG. 1. In this figure, the display period of duration T comprises 8 consecutive sub-scans , noted SB1 to SB8.

The display period of an image is 16.6 or 20 ms depending on the country. Each subscanning SBi comprises an addressing period Ai of fixed duration and a holding period Mu of variable duration. A weight, respectively 1, 2.4, 8, 16.32, 64 and 128, is associated with each subscanning, respectively SB1 to SB8, in order to obtain 256 levels of gray. The duration of each maintenance period is proportional to the weight associated with it. To obtain the highest gray level, 255 in this case, a value "1" (state on) is sent to each underscan and the

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 cell is then maintained in an on state during the 8 eight maintenance periods. The periods of illumination are distributed over the entire period of display of the image and the human eye performs an integration of these periods of illumination to obtain the corresponding gray level.

There are, however, some problems associated with this temporal integration of the lighting periods. A problem of false contours appears in particular when an object moves between two consecutive images. This problem manifests itself by the appearance of darker or lighter bands on normally noticeable gray level transitions. For colored PAP, these bands can be colored.

This problem of false contours is illustrated by FIG. 2 representing the sub-scans for two consecutive images, I and I + 1, comprising a transition between a gray level 127 and a gray level 128. This transition moves by 4 pixels between image I and image I + 1. In the figure, the ordinate axis represents the time axis and the abscissa axis represents the pixels of the different images.

The integration made by the eye amounts to integrating temporally along the oblique lines shown in the figure because the eye tends to follow the moving object. It therefore integrates information from different pixels. The result of the integration results in the appearance of a gray level equal to zero at the time of the transition between the gray levels 127 and 128. This passage through the zero gray level causes a dark band to appear at the level of the

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 transition. In the opposite case, if the transition passes from level 128 to level 127, a level 255 corresponding to a light band appears at the time of the transition.

A first known solution consists in "breaking" the high weights of the sub-scans to reduce the integration error. FIG. 3 represents the same transition as FIG. 2 but with seven sub-scans of weight 32 in place of the three sub-scans of weight 32,64 and 128. The integration error is then at most a gray level value equal to 32. It is also possible to distribute the gray levels differently but there is always an integration error.

In European patent application No. 0 978 817, compensation for the effects of false contours is carried out using a motion estimator which determines motion vectors for blocks of pixels in the image. These motion vectors are used to modify the data supplied to the elementary cells of the PAP. The general idea of this patent application is to detect the movements of the eye during the display of images and to provide cells with compensated data in movement so that the eye integrates the correct information. This process is illustrated in FIG. 4. This correction amounts to spatially displacing the sub-scans of the display period of an image as a function of the movements observed between the images so as to anticipate the integration that the eye will perform. human. The underscans are moved differently depending on

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 their weight and their time position in the video frame. This correction gives excellent results on transitions which cause false contour effects.

However, this correction has some drawbacks when objects appear or disappear between two images. FIG. 5 shows a field of motion vectors calculated with a prior art motion estimator. This vector field is representative of the movement between an image 1-1 and an image I. Each motion vector normally comprises a horizontal component and a vertical component corresponding to the horizontal and vertical displacement of a point between the two images. For reasons of clarity of representation, the image is represented as above only on a spatial dimension by the horizontal axis of the figure, the vertical axis representing time. In this figure, the display period of image I comprises 16 sub-scans. The periods for maintaining the sub-scans are hatched whatever the state, on or off, of the cells for this sub-scan. For each pixel of the image I is defined a motion vector indicating the direction and the amplitude of the movement relative to the image I-1.

In this example, we consider the case of an object moving in front of a background between image 1-1 and image I. Part of the background of image 1-1 disappears in image I while a new part of the background appears in image I. It then appears, during the display period of image I, a conflict zone

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 1 and an area of holes 2. These two areas are indicated by shaded areas in FIG. 5. The area of conflicts 1 is characterized by the crossing of motion vectors imposing two different displacements on the sub-scanning considered for a given pixel whereas the hole area is characterized by the absence of movement information for the sub-scanning and the pixel considered. These areas of holes and conflicts can cause defects in the processing of images. Correcting the displacement of the underscan, however, gives very good results to compensate for the effects of false contours and to solve the problems of image clarity.

The invention proposes a new way of using motion estimation to correct the effects of false contours.

The invention relates to a method for displaying video images on a plasma display panel comprising a plurality of elementary cells, the visualization of a video image being carried out using a plurality of underscans during which each elementary cell of said plasma display panel is either on or off, characterized in that it comprises the following steps: - from a sequence of main images of period T, at least one intermediate image is produced from a current main image and from a previous main image, said at least one intermediate image being compensated in movement to correspond to an image spaced by a duration T, OR

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 with a duration multiple of T, either from the current main image, or from the previous main image, and a sequence of resulting images is displayed consisting of main images and intermediate images, so that each image of said resulting sequence is displayed for a duration T, the duration T being less than the duration of the period T.

The invention also relates to a plasma display panel characterized in that it comprises a device implementing the method for displaying video images of the invention.

la figure 5 montre un exemple de champ de mouvement fourni par un estimateur de mouvement ; la figure 6 illustre un mode de réalisation du procédé de l'invention ; et Other characteristics and advantages of the invention will appear on reading the detailed description which follows and which is given with reference to the appended drawings, among which: FIG. 1 represents the temporal distribution of the sub-scans in a display frame d video image for plasma display panel; FIG. 2 illustrates the effects of false contours appearing when a transition moves between two consecutive images; Figures 3 and 4 illustrate known solutions to compensate for these effects of false contours;

FIG. 5 shows an example of a motion field provided by a motion estimator; FIG. 6 illustrates an embodiment of the method of the invention; and

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 Figure 7 shows an example of a device for implementing the method of the invention.

Figures 1 to 5 have been described in the preamble to this description.

According to the invention, it is proposed to create intermediate images compensated for movement in the sequence of video images to be displayed in order to limit the effects of false contours. The starting video images I-1, I, 1 + 1, ... of the sequence are called main images in the following description as opposed to the intermediate images.

The method of the invention is illustrated in FIG. 6 to be compared with FIG. 5. In FIG. 5, the main image I is displayed over a display period of duration T. According to the invention, an image is generated intermediate from main image 1-1 and main image I. This generation step consists, for example, of performing a linear combination between the gray levels of the pixels of the main image 1-1 and those of l main image I. This intermediate image is compensated for in movement as a function of its time position T between the main images 1-1 and I. T also corresponds to the duration of display of the intermediate image and it is less than T. In the example of FIG. 6, T is taken equal to T / 2 without it being possible to see there any limitation of the invention to this temporal position of the intermediate image. This intermediate image is

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bien entendu affichée entre l'image 1-1 et l'image I, plus particulièrement entre l'instant t=O et l'instant t=T=T/2. L'image I est affichée à la suite de l'image intermédiaire pendant une durée égale à T-T, soit T/2 dans le cas de la figure 6.

of course displayed between image 1-1 and image I, more particularly between time t = O and time t = T = T / 2. Image I is displayed following the intermediate image for a duration equal to TT, ie T / 2 in the case of FIG. 6.

In FIG. 5, the display period of image I comprises 16 sub-weights of weight 1, 2.4, 4.8, 8, 8.16, 16.16, 16.24, 24.24, 24.30 and 30 allowing the display of image I on 256 gray levels. In FIG. 6, given that T = T / 2, according to the invention, the first 8 sub-scans are assigned to the display of the intermediate image and the last 8 to the display of the image I. For obtain 256 gray levels for each of these images, the weight of these sub-scans is modified compared to FIG. 5. The weights 1, 2.4, 8.16, 32.64 and 128 are respectively assigned to the 8 sub-scans of the intermediate image and of the image I. Furthermore, the duration of the periods for maintaining the sub-scans is adapted so that the display period of the intermediate image and of the image I is respectively equal to T and TT.

As a variant, it is possible to envisage generating several intermediate images between images 1-1 and I. In this variant, it may then be necessary to reduce the number of possible gray levels for each image, for example switching from 256 gray levels at 128 gray levels, so that the entire display period of the intermediate images and of the image I does not exceed T.

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As indicated previously, the intermediate image is compensated in movement. For this, we define a first motion field representative of the movement between image 1-1 and image I. This first motion field, identical to that shown in Figure 5, corresponds to the movement between time t = 0 and the instant t = T. We then define a second motion field representative of the movement between the instant t = 0 and the time instant T. This second motion field is obtained by a bijective application which, with any vector of the first motion field, associates a vector with the same direction and the same amplitude to a multiplicative factor F close to T / T.

Then, in a first embodiment, a motion vector conforming to the second motion field is associated with each pixel of the intermediate image. This motion vector associated with a pixel of the intermediate image is identical for all the underscans of the display period of the intermediate image. Then, for each underscan of the display period of the intermediate image, each pixel of the intermediate image is shifted according to the motion vector associated with it. An intermediate image compensated in motion is thus obtained. The introduction of this compensated intermediate image in movement between the main images 1-1 and I compensates for the effects of false contours.

In a second more improved embodiment, each pixel of the display period is associated with each pixel of the display period of the intermediate image.

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 the intermediate image a motion vector conforming to the second motion field. In this improvement, the motion vector associated with a pixel of the intermediate image is a function of the time position of the sub-scanning considered. Then, for each sub-scan of the display period of the intermediate image, each pixel of the intermediate image is shifted according to the motion vector associated with it. Of course, the main image I is compensated in movement in the same way in accordance with the first field of movement. The introduction of an intermediate image and this compensation in movement of the intermediate image and of the main image I makes it possible to completely eliminate the effects of false contours.

Furthermore, this method has the advantage of greatly reducing the number of conflicts and holes during the display period of the image I and of the intermediate image as shown in FIG. 6. The zones of holes and conflicts are indicated by shaded areas to compare with Figure 5. The most significant reduction in the number of holes and conflicts is obtained for T equal to T / 2.

The invention is not limited to a value of T equal to T / 2 or to the simple addition of intermediate images. Another preferred example of the invention corresponds to T = 2T / 3. Only one in two main images is not displayed. For example, if the panel has 12 subscans during period T, the resulting image sequence will be displayed on 8 subscans. We will then display a main image I-1,

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 two intermediate images then a main image I + 1. The main image I is not displayed but the information it contains is used to calculate the two intermediate images.

Many structures are possible for implementing the method of the invention. An exemplary embodiment is shown in FIG. 7. An image memory 70 receives a stream of images to be stored. The size of the memory makes it possible to memorize at least 3 images, the image 1 + 1 being memorized during the processing of the image I using the image I-1. A calculation circuit 71, for example a signal processor, calculates the intermediate images and the motion vectors to be associated with the different images according to the method described above and supplies the ignition signals to control circuits for rows 72 and columns 73 of a plasma panel 74. A synchronization circuit 75 is provided for synchronizing the control circuits 72 and 73. This structure is given only by way of illustration.

Claims (7)

 CLAIMS 1) Method for displaying video images on a plasma display panel comprising a plurality of elementary cells, the visualization of a video image being carried out using a plurality of underscans during which each elementary cell of said plasma display panel is either on or off, characterized in that it comprises the following steps: - from a sequence of main images (I-1, I, 1 + 1, ...) period T, at least one intermediate image is produced from a current main image (I) and from a previous main image (I-1), said at least one intermediate image being compensated in movement to correspond to an image spaced by a duration T, or a duration multiple of T, either from the current main image, or from the previous main image, and a sequence of resulting images is displayed consisting of main images and images intermediaries, so that c each image of said resulting sequence is displayed during a duration T, the duration T being less than the duration of the period T. 2) Method according to claim 1, characterized in that an intermediate image compensated in movement is generated for each main image (I), the duration T being equal to half of the period T. <Desc / Clms Page number 14>  3) Method according to claim 1, characterized in that the duration T is equal to two thirds of the period T, and in that one main image out of two is not displayed. 4) Method according to any one of claims 1 to 3, characterized in that, in order to compensate in movement for said intermediate image, the following steps are carried out: a first motion field representative of the movement between the two images is defined

 main (I-1, I) from which said intermediate image is generated, a second motion field is defined from said first motion field representative of the movement between said two main images (I- 1, I) during the duration T of period T, and the vectors of said second motion field are applied to the pixels of said intermediate image. 5) Method according to claim 4, characterized in that, for each sub-scanning of the intermediate image, there is associated with each pixel of the intermediate image a motion vector conforming to the second motion field which is a function of the position temporal of said subscanning in the intermediate image, and each pixel of the intermediate image is shifted according to the motion vector associated with it. <Desc / Clms Page number 15>

 6) Method according to claim 4, characterized in that a motion vector conforming to the second motion field which is a function of the time position of said underscan in the intermediate image is associated with each pixel of the intermediate image, and each pixel of the intermediate image is shifted according to the motion vector associated with it. 7) Plasma display panel characterized in that it comprises a device implementing the display method of one of claims 1 to 6.