FR2737829A1 - Colour video image display for transmissive LCD screen - has light emitting unit and diffuser which illuminate pixel pair using alternately coloured light beams, with combined colour outputs generated - Google Patents

Abstract

The display includes a light emitting unit (1) with a screen diffuser (3) illuminating a transmissive liquid crystal display screen (2). The light emitting unit alternatively transmits green or magenta luminous beams. The liquid crystal display screen has pixels forming a mosaic structure, arranged in pixel pairs. One of the pixel pairs has a yellow filter passing green and red light and a cyan filter passing green and blue light.

Description

 The present invention relates to the display of a color video image on a transmissive liquid crystal screen.

 Transmissive liquid crystal screens develop the various shades of an image from three primary colors, either by an additive technique, or by a subtractive technique, or by a mosaic technique, or from a combination of the previous techniques. .

 The additive technique consists of combining with the aid of an optic three images in each of the primary colors obtained individually using three transmissive liquid crystal screens illuminated in each of the primary colors. It gives a color image of a very good definition equal to the resolution of each screen and of a good brightness but has the disadvantage of requiring a triple light box or three separate light boxes providing lighting in each of the three primary colors, three transmissive liquid crystal screens sharing the image in pixels with individual control of the transmission of light intensity and an optic for combining the three primary color images thus obtained.

 The subtractive technique consists of starting from a single light box illuminating in white light and operating in this white light a selective suppression of each of the three primary colors by means of three transmissive liquid crystal screens juxtaposed and interposed between selective filters of primary colors. It gives a color image of as good definition as the additive technique but of lower luminosity because the light coming from the light box must pass through a succession of three filters and three transmissive liquid crystal screens. The realization is a little simpler than with the additive technique because there is only one light box and no optics for combining primary images. However, there are problems of blurring due to the fact that the images with primary colors do not form in the same plane.

 The mosaic technique consists in using only a single transmissive liquid crystal screen illuminated in white light, the pixels of which have been divided into three groups, the elements of which are fairly distributed over the surface of the screen, which can be addressed separately, which are tinted to the three primary colors using individual filters and which form a three-color pattern repeating throughout the screen. This technique gives an image of less good definition than the previous two since its resolution stops at the level of the pattern. But it is much simpler to implement since it requires only a light box, a single transmissive liquid crystal screen and no optics for combining primary images.

 Also known are mixed techniques combining the previous techniques in order to achieve the best possible definition for a color image at the cost of the least possible complexity.

We know in particular by the European patent application
EP-AO 347 790 a color video image display comprising two transmissive successive liquid crystal screens placed in front of a white light box: a first transmissive screen with a red and green mosaic filter of liquid crystals controlling the transmission of the red and green image and a second liquid crystal screen controlling the transmission of the blue component of the image. This is a mixture of the subtractive technique and the mosaic technique seeking a compromise between the good resolution of the subtractive technique and the good brightness and simplicity of the mosaic technique. However, we end up with two crystal screens liquids instead of one in the mosaic technique and with a definition in green, which is the color to which the eye is most sensitive, reduced by half compared to what can be obtained in additive or subtractive technique .

 The object of the present invention is to display a color video image based on a single transmissive liquid crystal screen having an improved definition, in particular in green which is the color to which the eye is most sensitive.

 Its object is a remarkable color video image display in that it comprises a light box alternately emitting either a green luminous flux or a magenta (blue and red) luminous flux and a transmissive liquid crystal screen with a mosaic of pairs of pixels with yellow filter passing green and red and cyan filter passing green and blue.

 When the LCD screen is lit in green light, each of its yellow or cyan filter pixels controls the green tint so that it operates at maximum resolution. When the liquid crystal display is lit in magenta light, its yellow filter pixels control the red hue while its cyan filter pixels control the blue hue so that it only operates at half its resolution maximum. The result is two successive image components, one green, the other red and blue with different definitions, which are mixed at eye level. The defect of definition of the red and blue image component compared to the green image component is not perceived because the sensitivity of the eye is less in red than in green and less in blue than in the Red.

 Advantageously, in the mosaic of pixels with a yellow filter and a cyan filter covering the surface of the transmissive liquid crystal screen, the pixels with a yellow filter and with a cyan filter are distributed in a checkerboard pattern in the same proportion.

 According to a variant, the pixels with a yellow filter and with a cyan filter are distributed in a mosaic on the surface of the transmissive liquid crystal screen in an uneven proportion in number or in surface taking into account the difference in sensitivity of the eye between the red tint and blue tint.

 Advantageously, the light box comprises two nested networks of green and magenta fluorescent tubes.

 Other characteristics and advantages of the invention will emerge from the description below of an embodiment given by way of example.

This description will be made with reference to the drawing in which:
FIG. 1 represents, in profile section, a color video image display according to the invention,
FIG. 2 shows, in front section, the light box of the color video image display of FIG. 1,
FIG. 3 shows, from the front and schematically, the transmissive liquid crystal screen of the color video display of FIG. 1, and
- Figures 4, 5 and 6 are diagrams explaining the formation of a color image on the eye of an observer with the color video image display of Figure 1.

 As can be seen from FIG. 1, the display comprises a light box 1 which is seen by an observer O through a transmissive liquid crystal screen 2.

 The light box 1 contains, as shown in FIG. 2, two nested networks 20 and 21 of green and magenta fluorescent tubes which light up alternately, a diffuser 3 placed at the front homogenizing the lighting. It emits alternately, at a sufficient frequency (30 to 60 Hz) so as not to be discerned by the eye of an observer, a green light and a magenta light.

 The transmissive liquid crystal screen 2 comprises, as shown in FIG. 3, a mosaic of pairs of pixels with a filter colored in yellow (Y) and a colored filter in cyan (C) distributed in a checkerboard pattern according to the same proportion.

 During a first operating phase illustrated in FIG. 4, the light box 1 has its network 20 of green fluorescent tubes on and its network 21 of magenta fluorescent tubes off. The filters colored in yellow like those colored in cyan of the pixels of the transmissive liquid crystal screen 2 allow this green light (G) of the light box to pass, the intensity of which is modulated according to the commands applied to the different pixels of the transmissive liquid crystal screen 2 so that a green image component is obtained with the maximum resolution allowed by the splitting in pixels of the transmissive liquid crystal screen 2.

 During a second operating phase illustrated in FIG. 5, the light box 1 has its network 20 of green fluorescent tubes switched off and its network 21 of magenta fluorescent tubes switched on. The filters colored in yellow of the pixels of the transmissive liquid crystal screen 2 pass a red light (R) while the filters colored in cyan of the pixels of the transmissive liquid crystal screen 2 pass a blue light (B) The intensities of these red and respectively blue light points are then modulated as a function of the commands applied to the pixels associated with the filters colored in yellow and respectively with the filters colored in cyan of the transmissive liquid crystal screen 2 so that one obtains a red and blue image component with half the resolution of the transmissive liquid crystal display.

 As shown in Figure 6, the eye integrates the green image component and the red and blue image component presented to it alternately by the transmissive liquid crystal screen, provided that the frequency of succession of these two components image is fast enough, in practice of the order of 30 to 60 Hz.

 The perception of the definition of an image by the eye of an observer is mainly due to the green pigments (cones) which are in majority. It is much less influenced by the red pigments (cones) because they are less numerous and even less by the blue pigments (cones) which are even less numerous. In this way, the definition of the image of the color video display, which has just been described, is perceived by an observer as the definition of its green component which precisely corresponds to the maximum resolution of the transmissive screen at liquid crystals.

 Of course, the present invention is not limited to the example of embodiment described, but is susceptible of numerous variants accessible to the skilled person without departing from his mind. Thus the light box can be equipped with another type of lamps than fluorescent tubes for example, arc or halogen lamps. In the same way, the distribution of the yellow filter and cyan filter pixels on the surface of the transmissive liquid crystal screen may not be a homogeneous checkerboard distribution but be proportionate, by their number or their surface, more pixels with yellow filter than pixels with cyan filter, to take into account the difference in sensitivity of the eye between the red hue and the blue hue. In the same spirit, the succession of green and magenta information can be done image by image, as indicated above, or by interlacing of lines (succession of striped green / magenta images, followed by striped images in reverse magenta / green).

Claims (7)

 1. Color video image display characterized in that it comprises a light box (1) emitting alternately, either a green luminous flux, or a magenta luminous flux (blue and red) and a transmissive liquid crystal screen (2 ) with a mosaic of pairs of pixels with a yellow filter passing green and red and a cyan filter passing green and blue.  2. Display according to claim 1, characterized in that the cyan filter pixels (C) and the yellow filter pixels (Y) are distributed on the surface of its transmissive liquid crystal screen (2) according to a checkered mosaic.  3. Display according to claim 1, characterized in that the cyan filter pixels (C) and the yellow filter pixels (Y) are distributed on the surface of its transmissive liquid crystal screen in the same proportion.  4. Display according to claim 1, characterized in that the cyan filter pixels (C) and the yellow filter pixels (Y) are distributed on the surface of its transmissive liquid crystal screen in an unequal proportion in number or in surface taking into account the difference in eye sensitivity between the red tint and the blue tint.  5. Display according to claim 1, characterized in that its light box (1) comprises two nested networks (20, 21) of green and magenta fluorescent tubes which light up alternately.  6. Display according to claim 1, characterized in that its light box (1) comprises arc lamps.  7. Display according to claim 1, characterized in that its light box (1) comprises halogen lamps.