DE69107505T2 - Process for displaying images on a color dot matrix screen. - Google Patents

Description

The present invention relates to a method for displaying on a dot matrix color screen and in particular on such screens used for displaying measurements.

It is known to use grey tones (grey shadows in the Anglo-Saxon literature) on such a screen in order to avoid line deformation phenomena such as stairsteps and blinking phenomena; these phenomena tend to appear around monochrome zones, although it is clear that any colour image on a screen can be broken down into a finite number of monochrome zones. By widening the monochrome lines and controlling the grey tones of the screen pixels according to this widening, for example by changing the pulse width, it is indeed possible to avoid these phenomena; however, this seriously increases the computational effort required to process an image, which is detrimental to the fineness of the lines in the image, and it does not allow the iridescence phenomenon at the edges to be eliminated.

The present invention aims to avoid or at least reduce these disadvantages.

This is obtained by choosing the colours of the monochrome zones in such a way that it is possible to give the pixels surrounding these zones a colour at least similar to that of the pixels of the monochrome zone under consideration, but with a lower luminance.

According to the invention, a method is proposed for displaying images on a dot matrix color screen having identical pixels constructed from individual dots, ie from dots of the matrix, with certain dots colour filters whose transmission properties are controlled independently of one another, characterized in that for the display of a monochrome zone on the screen it consists in choosing a colour which can be obtained at least approximately by controlling the individual points of the pixels for the same transmission signal of the individual points in a first way and in a second way, each with a luminance per pixel which is higher in the case of the first way than that in the case of the second way, and in that the transmission of the individual points of those pixels which are located in the zone under consideration is controlled in the first way and the transmission of the individual points of those pixels which surround the zone under consideration is controlled in the second way.

The present invention will be better understood and further features will become apparent with the help of the following description and the related figures, which show:

- Fig. 1 shows the circuit diagram of a screen display device, which can be used both according to the invention and according to the prior art,

- Fig. 2 is an enlarged view of a pixel of the screen of Fig. 1;

- Fig. 3a, 3b, 3c traces according to the state of the art and without grey toning of a rotating line in white color on a dot matrix screen,

- Fig. 4a, 4b, 4c traces of the same line as in Fig. 3a, 3b, 3c, but with a line widening according to the state of the art,

- Fig. 5a, 5b, 5c traces of the same line as in Fig. 2 and 4, but with grey tint according to the invention,

- Fig. 6 and 7 enlarged views of screen parts according to Fig. 4 and 5,

- Fig. 8 and 9 are enlarged views corresponding to the tracks of Fig. 5a, 5b, 5c, but with a line of green or green-red color.

Fig. 1 is a simplified diagram of a device for displaying images in color on a dot matrix color screen 1, the images being defined by a graphics microcomputer 2 which stores tracking commands of information elements in a video random access memory 3, called VRAM (Video Random Access Memory). The video memory 3 contains a random access memory, a parallel/serial type shift register and a scanning circuit which enables the automatic and cyclic transfer of the lines of the random access memory to the shift register. The shift register of the memory 3 outputs the information to be displayed on the screen line by line. This information is received by a control stage 4 (driver in English literature) which is made up of a serial/parallel register followed by a latch register containing as many outputs as there are dots per line of the screen. A line counter 5 is associated with screen 1 and contains as many outputs as there are lines on screen 1; this counter allows the information to be taken into account as it arrives at control stage 4 in the lines of the screen for which it is intended. In the example described, screen 1 is a screen with 480 × 480 elementary dots or individual dots grouped into picture elements or pixels made up of four dots arranged in a square, which are white, green, red and blue when they are lit, that is to say when information reaches them from the control stage and the Line in which they are located is validated by line counter 5.

Fig. 2 shows, using a pixel, how the different colors are obtained: each pixel consists of four individual points W, G, R, B arranged in a square, each individual point containing a point of the matrix and the three individual points G, R, B containing a green filter, a red filter and a blue filter respectively, arranged in relation to the points in front of the screen; these three filters are in the form of squares of equal dimensions, joined together to form the three quadrants of another square, the fourth quadrant of which, which therefore contains no filter, is located perpendicularly in front of the point associated with the individual point W. When the screen is illuminated from behind with white light and when the four individual points are transparent to the backlight light, the screen emits green, red and blue light respectively perpendicular to these individual points and white light at the level of the fourth individual point W, to which no filter is associated, the light spot associated with this pixel being essentially a square. However, a mixture of colors is created if more than one individual point is transparent in the pixel in question; therefore, when the four individual points are transparent, both the central part, which in Fig. 2 is delimited by a circle of broken lines, and any part not covered by a filter are white, while the parts covered by a filter and located outside the circle have the color of the filters. Since any surface, which can be reduced to a line, is made up of pixels, all of whose individual points are transparent, an iridescence phenomenon occurs at the edges of this surface.

Regarding the four individual points of the same pixel, it should be noted that due to the filters for the same illumination of the screen and the same transmission signal of the individual points, the luminance vertically in front of the individual points G, R, B is four times weaker than perpendicular to the single point W to which no filter is assigned.

Figures 3a, 3b, 3c show how, in the prior art, an image of a white straight line segment can be obtained on the screen 1, representing, for example, a clock hand; this segment rotates clockwise around a point, Figures 3a, 3b, 3c being three temporally successive representations of this segment. These three figures are made up exclusively of pixels, the four individual points of which are transparent to light; each of these pixels of the straight line segment is therefore symbolized by a hatched square, which, as seen with the aid of Figure 2, represents the light spot related to a pixel, all of whose individual points are transparent.

In the images of Fig. 3a, 3b and 3c, both the stair step deformations and the iridescence phenomenon, which was mentioned in the description of Fig. 2, are large.

Figures 4a, 4b, 4c show how, in a known manner, by widening the line compared to Figures 3a, 3b, 3c, the effect of the steps is reduced, but the iridescence phenomenon remains. This widening process consists in surrounding the pixels forming the essentially monochrome straight line segments of Figure 3 by pixels which provide exactly the same lighting as the surrounding pixels, i.e. a white lighting obtained with the four transmitting individual points. To facilitate the understanding of this process, the squares of the pixels which were already illuminated in the case of Figure 3 have been hatched in Figure 4, as is also the case in Figure 5; these hatchings are exactly the same as those in Figure 3. In contrast, and although they provide the same illumination, the pixels added to the perimeter of the segments of Figure 3 have squares hatched in a different direction.

It should be noted that it is possible to reduce this iridescence phenomenon by means of grey tones obtained by temporally controlling the light transmission of the individual points, for example by means of a sawtooth control in which certain teeth are suppressed or by means of a pulse control with an adjustable width; however, such temporal control makes the realization of the screen display device very complicated and therefore more expensive.

Fig. 5a, 5b, 5c show how the phenomena of both stairsteps and iridescence observed in a display according to Fig. 3 can be greatly attenuated without attempting to achieve a gray tint by time control. To this end, the pixels that form the straight line segments of Fig. 3 are surrounded by pixels in which only the single point W is transparent; this has several consequences:

- the iridescence disappears and the steps are strongly muted,

- a grey tint is obtained around the straight segment,

- the determination of the image requires less computational effort on the part of the microcomputer than in the method of Fig. 4;

These latter two consequences are investigated with the help of Figs. 6 and 7.

In Fig. 5, the pixels in which only the individual point W, i.e. the individual point not assigned to a filter, is transparent, are represented by squares that are four times smaller than the squares of the pixels in which all individual points are transparent.

Fig. 6 shows the squares of three neighboring pixels P0, P1, P2, of which the four individual points are transparent; this situation arises in Fig. 4 when a pixel of a segment of Fig. 3 has been surrounded by pixels in order to widen the segment.

Fig. 7 shows the squares of three adjacent pixels P0, P1, P2, of which the four individual points of the central pixel P0 are transparent and of the other two pixels P1, P2 only the individual point W is transparent; this situation arises in Fig. 5 when a pixel of a segment of Fig. 3 has been surrounded by pixels of which only the individual point W was transparent. By adding coefficient 1 to the luminance of an individual point to which a filter is assigned and, depending on what was said above, coefficient 4 to the luminance of a point W, the amount of light supplied by the rotating pixels according to Fig. 6 reaches level 21, while in the case of Fig. 7 it only reaches level 15: the very bright white central pixel is located between two less bright white pixels; a shade of gray has therefore been achieved. Furthermore, an image that is created by making only one single point transparent in the pixels surrounding a monochrome area requires less additional computational effort from the microcomputer 2 of Fig. 1 than if two, three or four points are to be made transparent in the vicinity of the area under consideration. Of course, there are cases in which the monochrome area is created from pixels in which only one point containing a filter is transparent; these cases must be avoided in order to surround the area under consideration with pixels that have at least approximately the same color but are less bright.

Thus, a green monochrome surface is not obtained with pixels where only the single point G, which contains a green filter, is transparent, but for example with the transparent single points G and W to obtain a bright green, the outer periphery being formed by pixels in which only the single point G is transparent; Fig. 8 shows, in a line thus realized, a pixel in which the single points G and W are transparent and which is surrounded by two pixels in which only the single point G is transparent; thus the luminance for the central pixel has a level five times higher, provided that the single point W has a brightness level four times higher than the single points G, R and B, as seen above. Another way of obtaining green, but this time green-red, is to make the single points G and R transparent in a central line of pixels, the surroundings then being formed by pixels in which only the green single point is transparent; this way is illustrated in Fig. 9, which shows a first pixel forming part of the central line and whose single points G and R are transparent, and two pixels arranged on either side of the central line around the first pixel in which only their single point G is transparent; In this way, the luminance of the central line has a level twice as high as that of its surroundings.

The invention is not limited to the examples described with the aid of the figures relating to lines; for larger monochrome areas, all the pixels of the area are controlled like the pixels of the above-mentioned central lines, while the pixels of the outer perimeter of this area are controlled like the pixels surrounding the pixels of a central line.

The invention relates in general to any method which, for displaying a monochrome area on a dot matrix colour screen, consists in choosing a colour which can be obtained at least approximately as a function of the individual dots making up the pixels of the screen in a first and a second way, the brightness level per pixel being greater in the case of the first way than in the case of the second type; the method then consists in obtaining the colour according to the first type for the pixels of the zone under consideration and in obtaining the colour according to the second type for the pixels surrounding the zone under consideration.

Claims (4)

Method for displaying images on a dot matrix color screen having identical pixels made up of individual points (W, G, R, B), i.e. of points of the matrix, certain points being associated with color filters whose transmission properties are controlled independently of one another, characterized in that for the display of a monochrome zone on the screen (1) it consists in choosing a color which can be obtained at least approximately by controlling the individual points of the pixels for the same transmission signal of the individual points in a first way and in a second way, each with a luminance per pixel which is higher in the case of the first way than that in the case of the second way, and in that the transmission of the individual points of those pixels which are located in the zone under consideration is controlled in the first way and the transmission of the individual points of those pixels which surround the zone under consideration is controlled in the second way. 2. Method according to claim 1, which is carried out with a screen (l) whose pixels are formed by four individual points, namely a white (W), a green (G), a red (R) and a blue (B) individual point, characterized in that to obtain a white color it consists in commanding the passage of all the individual points for the pixels located in the area under consideration and in commanding the passage of only the green (G), red (R) and blue (B) individual points for the pixels surrounding the area under consideration. 3. Method according to claim 1, carried out with a screen (1) whose pixels are formed by four individual points, namely a white (W), a green (G), a red (R) and a blue (B) individual point, characterized in that to obtain a green color it consists in commanding the passage of the white (W) and green (G) individual points for the pixels located in the zone under consideration and in commanding the passage of the green individual point (G) for the pixels surrounding the zone under consideration. 4. Method according to claim 1, carried out with a screen (1) whose pixels are formed by four individual points, namely a white (W), a green (G), a red (R) and a blue (B) individual point, characterized in that to obtain a green color it consists in commanding the passage of the green (G) and red (R) individual points for the pixels located in the area under consideration and commanding the passage of the green point (G) for the pixels surrounding the area under consideration.