FR2634612A1 - Method for obtaining colour video pictures projected on a screen and device for implementing it - Google Patents

Abstract

The invention relates to video projectors. Three picture tubes 16, 17, 18, fed electrically at the same operating level, produce red, green and blue images 25, 26, 27, emitting more or less equal luminous fluxes. Projection optics 19, 20, 21 with different relative apertures modulate these fluxes in order to obtain, on a projection screen, superimposed red, green and blue images satisfying the known relationship between the brightnesses: 1 = 0.30 BR + 0.59 BG + 0.1 BB.

Description

PROCESS FOR OBTAINING VIDEO IMAGES
IN COLORS PROJECTED ON A SCREEN
AND ITS IMPLEMENTING DEVICE
Usually, a video projector comprises three video image tubes, each producing a spectrally selected image in one of the bandwidths of the conventional trichromatic analysis extending respectively in red1 green and blue-violet. These bandwidths are designated by the letters R, G, B. Each of the tubes is associated with a projection optic. Traditionally, the tubes and their images have an identical geometric conformation, as well as the projection optics associated with them. B, is not the same, in order to take into account the balance between the maximum levels of luminance, LR, LV, LB, of the red, green and blue images observed on the projection screen. For the trichromatic synthesis to be correct, according to the laws of physiological optics, LR, LV and LB must satisfy the relation
1 = 0.30 LR + 0.59 LV + 0.11 LB
Thus, the modulation is obtained by acting on the electrical supply.

In other words, if, as is generally the case, the three tubes are geometrically identical with their associated projection optics, and if the green tube operates at full speed, the red tube must operate at 0.30, or approximately half of its maximum speed, and the blue tube at 011 0.59 0.59 or 0.186 of its maximum speed. The operating modes are in the ratios 0.5 R; 1 V; 0.186 B.

This situation has drawbacks. The red tube and especially the blue tube are reduced to under-exploitation. The projection optics associated with them, on the other hand, are overused. However, due to the shortage of brightness from which video projection suffers, in general and particularly on large screens, the optics used have a very large relative aperture, commonly of the order of F = 1. Their diameter is large, commonly of l '' order of 150 mm. Their price is therefore high.

To overcome these drawbacks, the invention relates to a method for obtaining color video images projected on a screen and its implementation device.

According to the invention, in general, instead of modulating the electrical supplies of the tubes, their operating level is brought to the same level.

advantageously as high as possible, and these fluxes are optically modulated as a function of their own color, in particular by the choice of the relative aperture of the projection optics assigned to each color.

More specifically, the subject of the invention is a method for obtaining color video images projected on a screen, of the type according to which at least three video images emitting light flux are first generated, and the these images are then projected in coincidence on a projection screen, characterized in that the said flows are generated from electrical power supplies of substantially the same level, advantageously as high as possible, and in that one selectively then performs a optical modulation of these fluxes as a function of their respective natural colors, so that the images obtained on the projection screen exhibit luminances such as the maximum luminance of the red image, ie about 0.5 of that of the green image and that the maximum luminance of the blue image is substantially yes186 of that of the green image.

According to other characteristics of the method according to the invention - a projection optic is used for each image color and with respect to the product of the flux, emitted by the green video image, by the square of the opening relative of the projection optics assigned to the green color, this same product for the red image has a value of around 0.5 and this same product, for the blue image has a value of approximately 0.186.

- The power level generating the video images is brought to as high a value as possible and projection optics with different optical characteristics are used for the different image colors.

The subject of the invention is also a device for implementing the above method, of the type comprising at least three image-video tubes intended to produce images which emit light fluxes spectrally selected, respectively in the red, the green, blue, and associated with projection optics, device characterized in that, on the one hand, said picture tubes are intended to operate at the same level of electrical supply, and in that, on the other apart, the projection optics associated therewith have different relative apertures.

According to other characteristics of the device according to the invention - all the image-video tubes are intended to produce images emitting substantially equal light fluxes, and the structures of the associated projection optics are different.

- The geometric and optical structures of at least one of the video image tubes are different from those of the others and the structures of the projection optics associated with the various tubes are different.

The invention will be better understood from the detailed description below made with reference to the accompanying drawing. Of course, the description and the drawing are given by way of non-limiting example.

In this drawing FIG. 1 schematically represents the components of a video projector of a known type, the most usual.

 FIG. 2 schematically represents the components of a video projector according to the invention.

 FIG. 3 schematically represents a variant of the invention leading to obtaining a higher luminance on the projection screen than in the example of FIG. 2.

 FIG. 4 schematically represents a variant of the invention in which the green video image emits a higher flux than the red and blue video images.

FIG. 1 very schematically represents a video projector of traditional design. It consists of three image tubes 1, 2, 3, and three optical projection objectives 4, 5, 6, respectively associated with the three tubes. These tubes have identical geometric characteristics. They comprise screen panels, respectively 10, 11, 12, supporting real images produced1 on a luminescent coating, by electronic scanning from electron guns, respectively 13, 14, 15. The image produced at 10 in the tube 1 emits a flow of red light, the image at 11 in tube 2 emits a flow of green light, the image at 12 in tube 3 emits a flow of blue light. The power supply levels and therefore the operating regimes of the three tubes are different. The tube assigned to the green image works optimally at its maximum speed. The tube assigned to the red image operates at a speed located at a level of about 0.5 compared to that of the tube assigned to green. The tube assigned to the blue image, at a level of about 0.186 compared to the tube assigned to green.

 Ju made of these differences in operating levels, the fla emitted by the red video image has a value of about 0.5 of that of the flux emitted by the green video image, and the flux emitted by the blue video image has a value substantially of 0.186 of that of the flux emitted by the green video image.

These flux values will have an impact on the luminance values LR, LV, LB, of the red, green and blue images obtained on the projection screen, which values must satisfy the known relationship.
1 = 0.30 LR + 0.59 LV + 0.11 LB
The video images are projected onto a projection screen, not shown in the figure, and caused by electronic means to overlap as exactly as possible. The three objectives 4, 5, 6 are identical. They have the same diameter and same focal length. It is recalled that a lens having a diameter
D and a focal length F, its numerical aperture or number of apertures N is equal to F The inverse 1 = b is called the relative aperture of the lens.

DNF
For example, a photographic lens with a diameter of 18 mm and a focal length of 50 mm, has an aperture number equal to 2.8. Its relative opening is 1. In the example shown in Figure 1, for each of the three
2.8 objectives, the relative aperture is of the order of 1, as is currently the case for video projection. The diameter is substantially equal to the focal length, with a value which is commonly of the order of 150 mm.

The operating regimes of the three tubes being different, the flows emitted by the video images produced in 10, 11, 12 are also. The flux emitted at 10 by the red image has a value of approximately 0.5 compared to the flux emitted at 11 by the green image, and the flux emitted at 13 by the blue image has a value substantially of 0.186 by relation to the flux emitted by the green image. The relative apertures of the objectives 4, 5, 6 being the same, the images projected on the screen have luminances which are in the same proportions as the fluxes respectively emitted at 10, 11, 12.

If we take as a unit the luminance of the green image produced from the tube assigned to green, operating at its maximum speed, the luminance of the red image will have a value of approximately 0.5. The luminance of the blue image will have a value of approximately 0.186.

FIG. 2 very diagrammatically represents a video projector according to the invention. It consists of three image tubes 16, 17, 18, and three projection lenses 19, 20, 21, respectively associated with the three tubes. These tubes have identical geometric characteristics. They comprise screen panels, respectively 22, 23, 24, supporting real images produced, on a luminescent coating, by an electronic scan from electron guns, respectively 28, 29, 30. The image produced at 25 in the tube 16 is red, the image at 26 in the tube 17 is green, the image at 27 in the tube 18 is blue.

The operating modes of the three tubes are the same, brought to their highest possible level. These video images are projected onto a projection screen, not shown in the figure, and caused by electronic means to overlap as exactly as possible. The three objectives, 19, 20, 21, have different characteristics. The relative aperture of the lens 19, assigned to the red image, has a value equal to about 0.7 of that of the lens 20 assigned to the green image. The relative aperture of the objective 21 assigned to the blue image has a value equal to approximately 0.43 of that of the objective 20. In the example of embodiment according to the invention shown in FIG. 2, the focal lengths of the three objectives are equal and the diameters are different.The diameter of objective 19 has a value of approximately 0.7 compared to that of objective 20, and the diameter of objective 21 appreciably 0.43 compared to that of objective 20.

The operating modes of the three tubes being the same, as high as possible, the fluxes emitted by the video images produced in 25, 26, 27, are equal. The respective luminances of the red, green and blue images projected on the screen are then, as is known in geometric optics proportional to the squares of the relative apertures of the projection objectives: tion which are respectively assigned to them. Let (0.7) t ~ 0.5 for the luminance of the projected red image compared to that of the projected green image. And, (0.43) ~ 0.186 for the luminance of the blue image relative to that of the green image.

The same result would be obtained by varying both the focal lengths and the diameters of the objectives, or even only the focal lengths, provided that the fluxes emitted by the video images are modulated according to the invention. If, for the projection optics assigned to the red image, we designate its diameter by D1 and its focal length by F1, and, similarly, D2 and F2 for green, D3 and F3 for blue, we must have , assuming that the fluxes emitted by the red, green and blue images are the same

soit 0,7. Son diamètre est plus petit que celui de l'optique 20, dans la proportion de 0,7.Le diamètre de l'optique 21 affectée au bleu a un diamètre plus petit que celui de l'optique 20 dans la proportion de 0,43. In the example shown in FIG. 2, the projection optics 20 assigned to green has a relative opening of the order of 1. The relative aperture of optics 19 assigned to red has a relative opening of the order of

or 0.7. Its diameter is smaller than that of the optic 20, in the proportion of 0.7 The diameter of the optic 21 assigned to the blue has a smaller diameter than that of the optic 20 in the proportion of 0.43 .

This device according to the invention makes it possible to significantly reduce the cost price of all of the projection optics, and / or to increase the quality of the optics assigned to red and blue.

If it is not the concern to lower the cost price which predominates, it is possible, as in the example shown in FIG. 3, to increase the relative opening of the projection optics 31 assigned to the tube. green image V. It is, in this example, doubled, by multiplying its diameter by V or by 1.414. The relative aperture of the projection optic 32 assigned to the red picture tube R is approximately equal to 1. The relative aperture of the projection optics 33 assigned to the blue picture tube B is approximately 0.6. The advantage is to double the fluxes of the three video images and, consequently, to double the luminance obtained on the screen.

Compared to a conventional video projector, the cost price of the projection optics assigned to green is the only one which is increased. The price of the optics assigned to red does not change. The price of the optics assigned to blue decreases.

In the previous examples of devices according to the invention, the fluxes emitted by the three video images supplied by the tubes are equal. They may not be. One can, for example, modify the notably geometrical characteristics of the tube producing the green image in order to increase its luminous flux. It is then necessary to adapt the optical modulation of the fluxes, according to the invention. If one designates by cf 1 the flux emitted by the red image, by 2 the flux emitted by the green image and part 3 the emitted flux by the blue image, we must have

In the example shown in FIG. 4, due to the specific conformation of the tube V, the flux emitted by this tube V producing the green video image is doubled compared to the previous examples. The projection optic 34 which is assigned to it has a relative aperture equal to approximately 1. The flux emitted by the tube R producing the red video image is not modified compared to the previous examples. The relative aperture of the projection optics 35 which is assigned to it is equal to approximately I. Its diameter is approximately 0.7 compared to that of the optics 34, in the example shown in FIG. 4 where the doubling of the flux of the green image was concomitant with a magnification by 1.414 of the diameter of the image-video green and that of its projection optics. The relative opening of the projection optics 36 is equal to substantially 0.61.

We have, for the products of flux by the square of the relative opening
For red: 1 x (1) 2 = 1
For green: 2 x (1) 2 = 2
For blue: 1 x (0.61) 2 = 0.3
The relation 1 = 0.30 LR + 0.59 LV + 0.11 LB between the luminances LR, LV,
LB of the red, green and blue images on the projection screen is satisfied.

Claims (6)

 1. Method for obtaining color video images projected on a screen, of the type according to which at least three video images emitting light flux are first generated, and these images are then projected in coincidence. dence on a projection screen, characterized in that said fluxes are generated from electrical power supplies of substantially the same level, advantageously as high as possible, and in that one selectively then proceeds to an optical modulation of these fluxes function of their respective own colors, so that the images obtained on the projection screen have luminances such that the maximum luminance of the red image is approximately 0.5 of that of the green image and that the maximum luminance of the blue image is substantially 0.186 of that of the green image. 2. Method according to claim I, characterized in that a projection optic is used for each image color and that, relative to the product of the flux, emitted by the green video image, by the square of the relative opening of the projection optics assigned to the green color, this same product for the red image has a value of approximately 0.5 and this same product for the blue image, has a value substantially of 0.186. 3. Method according to claims 1 and 2, characterized in that the level of power supply generating the video images is brought to as large a value as possible and that is used for the different image colors of the projection optics having different optical characteristics.  according to claims I to 3 4. Device for implementing the above procedure, of the type comprising at least three image-video tubes intended to produce images which emit light fluxes spectrally selected, respectively in red, green, blue, and associated with projection optics, device characterized in that, on the one hand, said picture tubes are intended to operate at the same level of electrical supply, and in that, on the other hand, the projection optics which associated with them have different relative openings.  5. Device according to claim 4, characterized in that all the image-video tubes are intended to produce images emitting substantially equal light fluxes, and in that the structures of the associated projection pptics are different. 6. Device according to claim 4, characterized in that the geometric and optical structures of at least one of the image-video tubes are different from those of the others and in that the structures of the projection optics associated with the various tubes are different .