FR2618572A1 - Method for increasing the resolution of a system for taking images produced by a cathode-ray tube and device for implementation thereof - Google Patents

Abstract

In order to increase the resolution of images taken by a camera or a motion camera 3, 4 from images formed on the screen of a cathode-ray tube 1, a glass plate 7 with parallel faces is used, which may either be movable between a "rest" position and a "working" position, or be tiltable in different directions. Application: recording of synthetic images.

Description

The present invention relates to a method for increasing the resolution of a system for collecting images produced by a cathode-ray tube, as well as to a device for implementing this method.

In a CRT screen, the closer the pixels, the higher the definition. But a problem currently arises for computer generated images: the more pixels there are on the screen, the longer the time taken to generate an image.

If we want to reduce the production time of the images displayed by the cathode ray tube, we must be content with relatively poor resolution images.

The subject of the present invention is a method for increasing the image resolutions produced by a cathode ray tube and taken by a system, such as a frame-by-frame camera or a photo camera, without however increasing the generation time of these images.

The present invention also relates to a device for implementing such a method.

The method according to the invention consists in successively taking at least two images produced by the cathode ray tube, these images being offset between them by a fraction of the pitch of the points corresponding to the pixels of the images formed on the screen of the cathode ray tube which make up.

This offset is obtained by modifying the path followed by the light rays produced by the cathode ray tube over part of the path of these rays.

Said shift can be carried out, either at least once in the same direction, the amplitude of the shifts being substantially equal to the ratio of the pitch of the points making up these images and of the number of these shifts increased by one, or be carried out according to at least two different directions.

The device for implementing the method of the invention comprises, between the screen of the cathode ray tube and the sampling system at least one device modifying the path of light rays, which can either be movable between a position for which it intersects the light rays propagating from the screen of the cathode-ray tube towards the sampling device, and a position for which it does not intersect them, either be disposed on the path of these light systems, and have several different orientations or alternately have properties different vis-à-vis these light rays.

The present invention will be better understood on reading the detailed description of an embodiment, taken as a non-limiting example, and illustrated by the accompanying drawings, of which
Figure 1 is a simplified perspective view of a device con
form of the invention in which the light rays emitted by the screen
of a cathode ray tube follow a "normal" path
Figure 2 is a simplified perspective view of the device of the
Figure 1 in which said light rays follow, on a part of
their route, a route parallel to the normal route, and
FIG. 3 is a partial enlarged view of an image formed on the
plan of a sensitive surface of the image pickup device of the
Figure 2 device.

The method of increasing the resolution of the invention applies to the processing of images produced by trichrome cathode ray tubes, as well as by monochrome cathode ray tubes, the screen of which is formed by distinct phosphors defining the different pixels of their images.

To simplify the explanations, we will only talk about monochrome pixels later.

There is shown in Figures 1 and 2 the screen 1 of a cathode ray tube.

The electro-luminescent layer of this screen is formed of phosphors, for example round, but which may also be rectangular or oblong. When these phosphors are excited by the electron beam of the barrel of the tube, they define the pixels of an image displayed by the screen of the cathode ray tube. In Figures 1 and 2, there is shown, enlarged in a circle, some of these pixels, referenced 2 as a whole.

In order to record the images, for example synthetic images produced by a computer or a microcomputer, displayed by the screen 1, on a sensitive surface 3, such as a photographic film, a capture device is used. of views of which only objective 4 has been shown. This device for taking pictures can be, for example, a trigger camera seen by view or a photographic camera.

The image of the screen 1 formed by the objective 4 on the film 3 is referenced 5. As shown partially and enlarged in broken lines in FIG. 3, the image 5 is formed of a network of light points circular 6 (if the pixels 2 are circular, of course) which is homothetic (if one neglects the curvature of the screen 1 and the geometric deformations possibly introduced by the lens 4) of the array of pixels of the screen 1 .

The device shown in FIGS. 1 and 2 also includes a device 7 making it possible to slightly shift the image 5 without having to move the screen 1 or the camera or the film 3.

According to the invention, this offset is made so as to subject the points 6 to an abrupt translation of the value of approximately 1/2 step from their network in one of the North / South, East / West or North-West directions. / Southeast (or
North-East / South-West, which amounts to the same). These directions are identified in Figure 3.

Advantageously, as shown in FIG. 3, a north-west / south-east shift is carried out over a distance substantially equal to half the pitch, measured in this direction, of the network of points 6. The new network of points, thus obtained, has been shown in solid lines.

According to one embodiment of the invention, the device 7 advantageously includes one or more glass slides with parallel faces. anti-reflection treated. Firstly (Figure i), the device 7 is in the "rest" position -, that is to say that it is outside the path of the light rays arriving from the screen 1 to the objective 4. On open the shutter
(not shown) of the camera, and after a first exposure time corresponding to the half the correct position of the sensitive surface 3, the device 7 is put in place so that it arrives at a working position (Figure 2), for which it intersects said light rays. The screen is turned on again with the device 7 in place.

We then expose the second half of; the sensitive surface 3, in order to obtain a technically perfect negative or invertible. The "working" position of the device 7 is determined in a manner known per se to obtain the network of points 8 on the image 5; After a second exposure time, equal to the first, the shutter of the camera is closed. An image with double resolution compared to that obtained without the device of the invention is then obtained on the sensitive surface 3.

The device 7 is mounted on a mobile support on a guide rail (not shown) and actuated by an electric motor, for example a linear motor of which this guide rail is a part.

Instead of moving the blade or blades constituting the device 7, they can be left permanently in the path between the screen and the camera and change its inclination relative to the optical axis of the lens 4 to go from the "rest" position to the "work" position or vice-versa.

Of course, instead of a blade with parallel faces, it is possible to use any other optical or electro-optical device producing the same offset, for example a tilting or translating mirror, or an electro-optical device, the refractive characteristics of which can be modified. under the effect of an electric current or field.

Instead of producing a single offset, one can produce two or more offsets, by correlatively reducing the amplitude of these offsets (one third of steps for two successive offsets in the same direction), or by performing offsets in two or three directions different.

If the time taken for the device 7 to go from the "rest" position to the "work" position is not negligible compared to the exposure time of the sensitive surface 3, the shutter of the taking device can be closed views during the movement of the device 7 (assuming that this shooting device allows double exposure), either have a complementary shutter device in front of the lens 4, which is normally open and is closed during the movement of the device 7 .

The shifting method of the invention can also be implemented to increase the horizontal resolution of the image produced by a video tube, for example in the context of video projection. Such a video projection uses either a composite video tube (trichrome) or three monochrome tubes for red, green and blue respectively.

In such an application, there is interposed between the composite tube (or each monochrome tube) and the corresponding projection objective a North-South shift device (for example a blade with parallel faces) synchronized rotary, with a fixed phase shift, on the power supply frequency. Thus, we can double the horizontal definition of the image provided by the video projector: we can, for example, obtain an image at 1250 lines from an image received in 625 lines.

Of course, in the case of a video projector with three monochrome tubes, the three rotary shift devices will be synchronized with one another.

The synchronization of the rotary system on the sector frequency has the advantage of systematic phasing with the frame signal of the video image.

Claims (14)

1. Method for increasing the resolution of a sampling system  of images produced by a cathode ray tube, characterized by the fact  that we take successively at least two images produced by the tube  cathodic, these images being shifted between them by the value of one  do we split the pitch of the points corresponding to the pixels of the images formed  on the screen of the cathode ray tube that make them up. 2. Method according to claim 1, characterized in that the deca  the image age is obtained by modifying the path followed by the rays  light produced by the cathode ray tube on part of the path of  these rays. 3. Method according to claim 1 or 2, characterized in that  shifts the images taken at least once in the same direction,  the amplitude of the offsets being substantially equal to the pitch ratio  of the points making up these images and of the number of these offsets aug  lied with a unit. 4. Method according to one of claims 1 to 3, characterized in that  shift the sampled images in at least two directions  different. 5. Method according to one of claims l to 4, used to increase  the horizontal resolution of the image produced by a video tube,  characterized by the fact that the images it produces are shifted  frame rate of these images. 6. Device for increasing the resolution of a sampling system  ment (3,4) of images produced by a cathode ray tube (1), characterized  by the fact that it comprises, between the screen of the cathode ray tube and the  sampling system, at least one device (7) modifying the path  of light rays. 7. Device according to claim 6, characterized in that the  device modifying the path of light rays is movable between a  position for which it intersects propagating light rays  from the cathode ray tube screen to the sampling device, and  a position for which it does not intersect. 8. Device according to claim 6, characterized in that the  device modifying the path of light rays is arranged on the  path of light rays propagating from the screen of the cathode ray tube  to the sampling device and that it can have several orien  different tations. 9. Device according to claim 6, characterized in that the  device modifying the path of light rays is arranged on the  path of light rays propagating from the screen of the cathode ray tube  to the sampling device and alternately presents props  different laughs with regard to these light rays. 10. Device according to one of claims 6 to 8, characterized by the  that the device modifying the light ray path com  carries at least one glass slide with parallel faces. 11. Device according to one of claims 6 to 10, characterized by the  makes the sampling device a trigger camera  view by view. 12. Device according to one of claims 6 to 10, characterized by the  fact that the sampling device is a cinematographic device  or a VCR camera. 13. Device according to one of claims 6 to 10, for the application  on television, with a three-color video tube, characterized by the fact  that the device modifying the path of the light rays is rotatable  and synchronized with the mains supply frequency. 14. Device according to one of claims 6 to 10, for application  on television, with three monochrome tubes (R, G, B), characterized by  the fact that there is a rota device in front of each of the tubes  tif modifying the path of the moon rays and that these three dispo  rotary devices are synchronized with each other and on the frequency  power supply.