EP1647149A2

EP1647149A2 - Device for displaying color images

Info

Publication number: EP1647149A2
Application number: EP04767890A
Authority: EP
Inventors: Laurent Blonde; Khaled Sarayeddine; Jonathan Kervec
Original assignee: Thomson Licensing SAS
Current assignee: THOMSON LICENSING
Priority date: 2003-07-17
Filing date: 2004-07-12
Publication date: 2006-04-19
Also published as: FR2857814A1; JP2007529026A; JP4487091B2; WO2005011288A2; WO2005011288A3; US20070024813A1; KR20060033022A; CN1836450B; MXPA06000644A; KR101035679B1; US7914155B2; CN1836450A

Abstract

A display device comprises rotating color wheels (12, 14), for generating a periodic color beam, and an imager (16) which modulates the color beam on the basis of a received video signal (V RGB). At each period, the color beam (8) successively adopts a plurality of base colors (a, ss, <) synchronised with the images generated by said imager for each base color (a, ss, ?). The tint of the base colors (a, ss, ?) can be modified by setting the relative position ( PHI ) of the color wheels (12, 14), in order to adapt said colors, as well as possible, to the received video signal (V RGB).

Description

Color image display device

The invention relates to a device for displaying color images. In color image display devices, the color displayed at each point is generally obtained by the combination by additive synthesis of several basic colors. The weighting of the different colors in the combination determines the displayed color. The combination by additive synthesis of the basic colors can take various forms. It can be achieved by superimposing different beams which each correspond to a basic color. According to another solution, used for example in single-imager projectors and overhead projectors (which use a single imager or modulator to process all the basic colors), the combination is obtained by the very rapid succession of the display of each basic color, which the eye integrates into a resulting color (sequential method). Conventionally, three basic colors are used. These three basic colors are in most display systems red, green and blue. By the combination of these three colors with variable weights, we can obtain at each point a wide range of colors, which describes according to classical representations of chromaticity (CIE type) the area of a triangle whose vertices represent the colors of based. In display devices which use such a solution, the set of colors which it is possible to display is therefore limited and determined during design as a function of the basic colors used. For example, in a projector or overhead projector whose basic colors are obtained by the successive passage of colored filters in front of a white light source, the colors of the filters fix the vertices of the triangle whose surface corresponds to the whole colors that can be displayed by the projector or overhead projector. In order to improve the brightness of such a display device, patent application EP 0 749 250 has proposed varying the saturation of the basic colors by radial displacement of a specific colored wheel relative to the light beam. This colored wheel has saturated colors in the center and gradually becomes desaturated at the periphery. The user can thus change the brightness and, conversely, the saturation of the displayed images. This solution, however, only very specifically extends the possibilities of obtaining colors by the display device. In particular, the effect is necessarily identical on all the basic colors. In addition, the result obtained is comparable to a conventional brightness adjustment. In order to compensate for the degradation of the filters over time, patent application WO 95/1172 proposes to make the intensity of the light source independently adjustable for each filter. This adjustment thus makes it possible to modify, as in the previous solution, the saturation of the basic colors, but also leaves the hue of each unchanged, which limits the possibilities of adjustment. In addition, varying the intensity at the frequency of passage of the filters makes the lamp supply system complex. The invention aims to improve the color rendering of display devices. To this end, it provides a display device in which the color at a point is obtained by the combination of at least a first and a second base color, comprising means for modifying the tint of the first base color. Preferably, the device comprises means for receiving a video signal and means for determining the hue of the first basic color as a function of the video signal. Thus, basic colors are used which are best suited to the images to be displayed. The invention also provides a display device comprising means for generating a periodic colored beam and means for modulating the colored beam as a function of a video signal received, the colored beam successively taking on a plurality of colors in each period. base, comprising means for modifying the hue of at least one of said base colors. Preferably, the device comprises means for determining said shade as a function of the video signal received. The invention proposes, for example, that the generation means comprise first and second colored wheels successively crossed by a light beam, each colored wheel carrying a plurality of colored filter sectors and being driven in rotation, and that the position of the second wheel colored relative to the first colored wheel is variable. Preferably, the device includes means for determining said position as a function of the video signal received. In order to maintain the initial appearance of the images to be displayed, the device can include means for processing the video signals received as a function of said shade. In particular, the processing means generate data intended for the modulation means. The invention also provides a display device comprising means for generating a colored beam and means for modulating the colored beam, the modulation means generating for a determined duration an image to be displayed in a determined color, in which the colored beam successively takes at least two distinct colors during the determined period in order to obtain the resulting determined color. Advantageously, the colored beam takes on at least one of said distinct colors for a variable duration so as to vary said determined color. Other characteristics and advantages of the invention will become apparent in the light of the detailed description which follows, given with reference to the appended figures, in which: - Figure 1 shows an example of a display device produced in accordance with the teachings of the invention ; - Figure 2 shows a colored wheel of the display device - Figure 3 shows the colored filters crossed by the light beam as a function of time; - Figure 4 shows the color of the colored beam as a function of time; - Figure 5 shows the basic colors of the device for several configurations of colored wheels; - Figure 6 shows an alternative embodiment of the mechanism of the colored wheels. The display device shown in Figure 1 is a single-imager projector. It comprises a light source, represented here diagrammatically by the association of a reflector 2 and a light source 4, which generates a polychromatic light beam 6 whose spectrum extends over the whole range of visible frequencies and that we can therefore name it for simplicity colorless beam, even if in reality the light power is generally not constant as a function of frequency. In this case, using a light source of the ultra-high pressure mercury vapor lamp type, the spectrum of the beam originating from the source mainly comprises a blue line, a green line, a yellow low power line and a red part. as a continuum. The colorless beam 6 successively passes through a main colored wheel 12 and a secondary colored wheel 14 and therefore emerges under in the form of a colored light beam 8. Each colored wheel 12, 14 includes colored filters in the form of sectors, as will be explained in detail below. The main colored wheel 12 is rotated by a first motor 22 while the secondary colored wheel 14 is rotated by a second motor 24. A control unit 26 controls the rotation of the first motor 22 and the second motor 24 and sends Sync synchronization information to a pilot 28 of a matrix imager (or modulator) 16, in order to synchronize the image generated by the imager 16

(that is to say the modulation carried out at each point of the imager 16) with the color of the colored beam 8, as explained in detail below. The main colored wheel 12 and the secondary colored wheel 14 are identical according to the preferred embodiment, namely both composed of three angular sectors of 120 ° of respective colors yellow (Y), magenta (M) and cyan (C), as shown in FIG. 2. The main colored wheel 12 and the secondary colored wheel 14 are parallel and are driven in rotation in the same direction (with respect to the incident colorless beam) with an essentially identical angular speed in stabilized operation (apart from possible phase shifts as explained below). In the embodiment shown in FIG. 1, the first motor 22 and the second motor 24 which are face to face therefore rotate in opposite directions, with an essentially constant speed. By adequately controlling the first motor 22 and the second motor 24 by means of the control unit 26, it is therefore possible to control the phase shift of the secondary colored wheel 14 relative to the main colored wheel 12. FIG. 3 represents the colored filters Y, M or C crossed by the light beam over a period of rotation of the colored wheel main 12, in several cases of phase shift of the secondary colored wheel 14. In the example shown, the main colored 12 and secondary 14 wheels rotate clockwise when viewed from the light source, as shown in the figure 2; this implies a relative rotation in the trigonometric direction of the beam with respect to each wheel, and therefore a coloring Y, then M, then C for each wheel. In FIG. 3, the line P represents the colored filters Y, M, C of the main colored wheel 12 successively crossed by the colorless incident beam 6 over a period of rotation thereof. The lines S _Φ O, S _ΦI , Sφ ₂ represent the colored filters Y, M, C of the secondary colored wheel 14 successively crossed by the beam, each for a determined value Φ0, Φl, Φ2 of the phase shift of the secondary colored wheel 14 with respect to the main colored wheel 12. (Φ0 = 0 °, Φl = 60 °, Φ2 = 120 °.) Remember that a yellow filter Y stops the short wavelengths and therefore the blue line B while it lets the medium and long wavelengths pass (green line G and red part R of the spectrum). A magenta filter M stops mean wavelengths (green line G) and lets pass the blue line B and the red continuum R. Finally, a cyan filter C stops long wavelengths (red continuum R) and lets pass the green V and blue B lines. Successive passage through two filters of different colors will therefore allow only one of the three colors (red R, green G, or blue B) to pass according to the following rule:

- yellow Y and magenta M allow only red R to pass;

- yellow Y and cyan C let only the green G pass;

- magenta M and cyan C allow only the blue B to pass. By applying these principles, the color Cφ ₀ , C _Φ ι, Cφ ₂ of the colored beam 8 resulting from the passage through the main colored wheel 12 and the secondary colored wheel 14 is therefore as given in FIG. 4. Like Figure 3, Figure 4 shows a period of rotation of the main colored wheel 12 for the three phase shift values Φ0, Φl and Φ2. We can already see that thanks to the phase shift of the secondary colored wheel 14 relative to the main colored wheel 12, it is possible to modify the tint of the successive colors (over a period) of the colored beam 8. As we have seen precisely, the pilot 28 controls the imager 16 synchronously with the rotation of the colored wheels 12, 14 thanks to the information Sync. According to a possible embodiment, the imager 16 is controlled to display images corresponding to the colored segments of the main colored wheel 12. The imager 16 therefore modulates the colored beam 8 according to a fixed image over each third of period Tl , T2, T3 during which the same color filter of the main color wheel 12 is crossed by the colorless beam 6. As clearly visible in FIG. 3 in the case of the phase shift Φl, the beam can on the other hand pass successively through color filters different over the same third of period T1, T2, T3 on the secondary colored wheel 14. In this case, as visible in FIG. 4, the color of the colored beam 8 may vary over the same third of period T1, T2, T3; in a classic representation of chromaticite, the color of the colored beam 8 over a third of the period, which constitutes a basic color for the display device, will then be the barycenter of the different color points of the colored beam 8 weighted by their duration over the third of the period. FIG. 5 thus represents the basic colors Oφj, β _φ j, Y _J of the projector, that is to say the colors of the colored beam 8 over each third of period Tl, T2, T3 during which the imager generates a still image, for the different values Φi of the phase shift of the secondary colored wheel 14 with respect to the main colored wheel 12. The basic colors α _φi , β _Φ j, γ _φ j are therefore the vertices of the triangle whose surface represents l set of colors displayed by the display device when the phase shift of the secondary colored wheel 14 relative to the main colored wheel 12 is equal to Φi. Notably, since over each third of period T1, T2, T3 the filter of the main colored wheel 12 crossed by the colorless beam 6 5 stops one of the parts of the spectrum (blue line, green line or red continuum), the base color α _φi , β j, corresponding γ _φi is necessarily located on the segment delimited by the other two lines (RB or RG or GB). The basic colors Oφj, β _φi, _φi γ are thus each located on one side of the RGB triangle.

10 As can be clearly seen in Figures 4 and 5, in the case of a phase shift equal to Φ2 = 120 °, the basic colors are therefore green G, red R, blue B. We understand that, in this case, the data video to be displayed received at a video input 36 in a conventional format (CVBS or RGB for example) only needs processing

15 conventional since the basic colors R, G, B are those generally used in video. On the contrary, for the other phase shift values, such as for example Φ0 or Φl, the basic colors α, β, y (for example C- _ΦO , βφo, YΦ _O or OΦ _I , βφi, Y _ΦI ) are different from the triplet classic R, G, B and on

20 therefore proceeds within a processing unit 32 to calculate the coordinates of the color to be displayed for each pixel in the reference frame of basic colors. From the video data received at the video input 36 (conventionally expressed in the form of a v _RGB video vector

25 in the red color scheme R, green G, blue B), the processing unit 32 calculates the data in the basic color _scheme α, β, y (vector _αpγ ) by multiplication by a matrix (M) _{RGB → has?} obtained from the coordinates of the basic colors α, β, Y in the coordinate system R, G, B.

"* U» ₀ φγ ⁼ \ Aï) _{RGB →} . V _RGB The coordinates V _a? of each pixel in the reference frame of the basic colors α, β, Y therefore corresponds to the projection of the color of the pixel on the axes (Oα), (Oβ), (Oγ) - O corresponding to black. Thus, for each pixel to be displayed, the values to be assigned to this pixel are obtained by means of the imager 16 controlled by the pilot.

28 during each third of period T1, T2, T3, each third of period

Tl, T2, T3 corresponding, as we have seen, to one of the basic colors α, β, Y - The projector also includes an evaluation unit 30 which determines the basic colors α, β, Y to be used and the corresponding phase shift Φ, preferably as a function of the video data received γ ^Y RGB According to one possible embodiment, the phase shift angle Φ chosen is such that, in the chromaticite diagram, the triangle Tφ having the basic colors as vertices corresponding α _φ , β _Φ , γ _φ contains a determined part (for example 95%) of the color points of a group of successive images. Of course, values other than 95% can be used, preferably greater than 90%. To do this, we calculate for example the percentage p _φ of color points of the group of images (for example 12 successive images) for different values of Φ (over a range extending from -120 ° to 120 ° or alternatively from 120 ° to 240 °); then we choose the value of Φ such that P _Φ is the closest to 95%. If several values are suitable, one can take the value Φ corresponding to the triangle T _φ of minimum area, which corresponds to a maximum brightness of the projector. The phase shift Φ thus determined and the corresponding basic colors α, β, Y (see above and FIG. 5) are then transmitted respectively to the control unit 26 (for effective realization of the phase shift of the secondary colored wheel 14 relative to wheel main color 12) and to the processing unit 32 (for determining the matrix () _{ΛGB → αPr} to be used to obtain the video data in the reference frame of the basic colors α, β, Y). Preferably, the phase shift is determined periodically, for example with a frequency of 1 Hz. Thanks to the arrangement which has just been described, the projector uses optimized basic colors, in particular as regards their tint, depending on the images it should display. FIG. 6 represents an alternative mechanical embodiment of the colored wheels and their control device. According to this variant, the main colored wheel 112 is rotated by a motor 122 at its axis 123 (as in Figure 1). In addition, an elastic belt 129 transmits the rotational movement of the axis 123 of the main colored wheel 112 to the axis 125 of the secondary colored wheel 114. Thus, under normal conditions (fixed phase shift), the secondary colored wheel 114 at an angular speed which is naturally identical to the main colored wheel 112. The elastic belt 129 is kept under tension by means of an adjustable roller 127. By translation of the adjustable roller 127 in the direction x, the tension of the elastic belt can be modified 129 in order to obtain a brief acceleration or deceleration of the secondary colored wheel 114 (relative to the main colored wheel 112). Thus, the phase shift Φ of the secondary colored wheel 114 can be varied relative to the main colored wheel 112. It can also be noted that, in the embodiment of FIG. 6, the main colored wheel 112 and the secondary colored wheel 114 are essentially parallel but are not coaxial. The colorless beam 106 therefore crosses the two colored wheels 112, 114 in a region where they overlap. It is particularly clear in this case that the phase shift Φ to be considered is not the angular difference of a sector (for example Y ₂ ) of the secondary colored wheel 114 with respect to the identical sector (in the example Yi) of the main colored wheel 112, but the difference on the colored wheel as shown in FIG. 2 between the angle where the second colored wheel 114 receives the light beam 106 and the angle where the first colored wheel 112 receives the light beam 106. Thus, in FIG. 6, the phase shift of the secondary colored wheel 114 relative to the main colored wheel 112 is of the order of -60 °. The invention is not limited to the embodiments which have just been described. In particular, in order to limit the movements necessary for adjusting the phase shift of one colored wheel relative to the other, each colored wheel may carry a larger number of sectors of reduced size, with repetitions of the different sector colors.

Claims

1. Display device in which the color at a point is obtained by the combination of at least a first (α) and a second (β) basic colors, characterized by means for modifying the tint of the first color of base (α).

2. Display device according to claim 1, comprising: - means for receiving (36) a video signal (V _RGB ) _I

- Means for determining (30) the tint of the first base color (α) as a function of the video signal (V _RGB ).

3. Display device comprising means for generating a periodic colored beam (8) and means (16) for modulating the colored beam as a function of a received video signal (V _RGB ), the colored beam successively taking up each period a plurality of basic colors (α, β, Y), characterized by means for modifying the hue of at least one of said basic colors (α, β, γ) <

4. Display device according to claim 3, comprising means for determining said shade as a function of the video signal received V _RGB ) _

5. Display device according to claim 3, in which the generation means comprise a first (12) and a second (14) colored wheels successively crossed by a light beam (6), each colored wheel (12, 14) carrying a plurality of colored filter sectors (Y, C, M) and being driven in rotation, and in which the position (Φ) of the second colored wheel (14) relative to the first colored wheel (12) is variable.

6. Display device according to claim 5, comprising means for determining said position (Φ) according to the received video signal (V _RGB ).

7. Display device according to one of claims 3 to 6, comprising means for processing (32) video signals (V _RGB ) received as a function of said shade.

8. Display device according to claim 7, in which the processing means (32) generate data ( _αβγ ) intended for the modulation means (16).

9. Display device comprising means for generating a colored beam (8) and means for modulating (16) the colored beam (8), the modulation means (16) generating for a determined period an image to be displayed in a determined color (α _Φ ι; βφi; Y _ΦI ), characterized in that the colored beam (8) successively takes at least two distinct colors (G, Y; R, M; B, C) during the determined period ( Ti; T ₂ ; T ₃ ) in order to obtain the resulting determined color (Û _I ; βφi; Y _Φ I).

10. Display device according to claim 9, in which the colored beam (8) takes at least one of said distinct colors (G, Y) for a variable duration (tu; tι ₂ ) so as to vary said color. determined (Q _Φ I).