FR2561475A1 - Device for reflecting to infinity a video image viewed under a wide angle. - Google Patents

Abstract

A video image I formed on a screen 22 is magnified by a relay lens 24 before being sent to a semi-transparent plate 23 intended to position the magnified image I' in the focal surface F of a spherical mirror 20 at the centre of which is positioned the viewer O. The relay lens 24 allows an increase in the field by which the image is viewed and an enlargement of the field is further possible by juxtaposing images obtained on the basis of several screens associated with respective relay lenses and semi-transparent plates. The invention can be used in particular for environment reconstruction in a simulator.

Description

 Device for infinitely returning an empty image observed from a wide angle.

 The present invention relates to a device for infinitely returning a video image observed at a wide angle.

 By "video image" is meant here any image produced on a screen, for example on a cathode ray tube screen regardless of the generation mode.

 Such a device can be used in particular, but not exclusively, for the reproduction of the environment in a simulator, for example for the reproduction of the landscape in an airplane simulator.

 In the context of this particular application, it is known to use a device as illustrated in FIG. 1, with a spherical mirror t0 of axis orthogonal to that of a cathode ray tube 12 on the screen of which is formed the video image to be returned to the mirror. A semi-reflecting plate 13 is arranged at li50 with respect to these axes passing through their point of intersection M, the locations of the tube 12 and of the plate 13 being such that the latter places the image formed on the screen in the focal surface F of the spherical mirror 10. From the observation point O located in the center of the mirror 10, the field a along which the image is observed is determined by the width Q of the image formed on the tube 12 and by the distance r / 2 between point O and focal surface F on the axis of the mirror. We indeed have a9 Arc tg Q / r. In a simulator, the distance r (radius of the mirror) is imposed. To increase the field, it is possible to seek to increase the width Q, but this width cannot exceed a maximum value Sm beyond which the tube 12 is located on the path of the light rays reflected by the mirror 10. also seek to juxtapose several tube-semi-reflective plate-mirror assemblies but one would then come up against the impossibility of forming juxtaposed images without physical interference from the tubes.

 The object of the present invention is to provide an infinite deflection device by means of which it is possible to overcome the limits indicated above of the device of FIG. 1.

 This object is achieved by means of a device of the type comprising a spherical mirror and a semi-reflecting plate intended to place in the focal surface of the mirror an image of the video image formed on a screen, in particular a screen of cathode ray tube. , device in which, in accordance with the invention, a relay lens is placed between the screen and the semi-reflecting plate in particular to enlarge the video image formed on the screen.

 Thus, the actual image on the screen can be enlarged by the relay lens to form an image placed in the field of the spherical mirror without obscuring the reflected rays.

 The gain thus achieved on the size of the tube can be taken advantage of by constituting a device comprising a plurality of screens each associated with a lens and with a particular semi-reflective strip so as to place, on the focal surface of the spherical mirror, several images juxtaposed. In this way, an increase in the field is obtained without encountering the material impossibility of juxtaposition of several tubes with the system of the prior art.

 According to another advantageous feature of the device according to the invention, the relay lens can be arranged not only to enlarge the actual curved image formed on the screen, but also to transform it into a spherical image placed on the focal sphere of the mirror. through the semi-reflective strip.

 According to yet another particularity of the device according to the invention, a color image is formed by superposition of several real monochrome images formed on screens of tubes with distinct cathode rays, this superposition being produced by optical means comprising color filters. Compared to a three-color tube, the use of several monochrome tubes allows both better definition and greater brightness.

Other features and advantages of the device according to the invention will emerge on reading the description given below, by way of indication, but not limitation, with reference to the appended drawings in which
- Figure 1, already described, illustrates a known device for reference to infinity;
- Figure 2 is a schematic view of an embodiment of a device according to the invention
- Figure 3 is a schematic view of another embodiment of a device according to the invention using several monochrome tubes to form a color image
FIG. 4 is a schematic view of yet another embodiment of a device according to the invention using several juxtaposed assemblies with tube, relay objective and semi-reflective strip of the device in FIG. 4.

The device schematically represented in FIG. 2 comprises a convex spherical mirror 20, a cathode ray tube 22, and a semi-reflecting plate 23 and a relay lens 24 placed in front of the screen of the tube 22 on the path of the light rays between this screen and the blade 23. The assembly is arranged so as to refer to infinity, for an observer located in the center
O of the mirror, the image formed on the screen of the tube. In the example illustrated, the axis of the mirror and the axis common to the mirror and the axis common to the tube and to the objective are orthogonal, and the semi-reflective strip is inclined at 450 with respect to these two axes passing through their point of intersection M.

 The relay objective 24 is constituted by a set of lenses intended to enlarge the real image I formed on the screen of the tube 22 and to transform this curved image into a spherical image T which is placed on the focal surface F of the mirror 1 by the semi-reflecting plate 23. Thus compared to the device of FIG. 1, an increase in the field is possible with a mirror of the same radius since the image I ′ can be placed in the field of the mirror 20 without obscuring the rays reflected by it. In addition, the presence of a relay lens 24 can be used to reduce the aberrations resulting from the transition from an image on a cathode ray tube screen to a spherical image. The production of an object having the function of enlarging and modifying the shape of an image, by means of a set of lenses, is a well-known operation in itself which it is not necessary to describe here in detail. In the case where the image formed on the screen of the tube 22 is a color image, the objective 24 can also be corrected in achromatism as is also known per se.

 A preferred field of application of the invention is that of the reproduction of the environment in a simulator, in particular the reproduction of the landscape in an airplane simulator, the eye of the user being at observation point 0. It is desirable that the image observed has a high definition. However, with a three-color tube, the utility mask in the tube creates by its structure, a close link between the size of the tube and the minimum definition of the image produced. The search for a high definition image leads to the use of a large tube, therefore a relatively expensive large object.

 In order to overcome the drawbacks linked to the presence of the mask in a three-color tube, it is possible to use several monochrome tubes associated with dichroic filters as shown in FIG. 3.

 As in the embodiment of FIG. 2, there is a spherical mirror 30 and a semi-reflecting plate 33 arranged so as to bring back an intermediate image I 'on the focal surface F of the mirror. However, in this case, the color image I ′ is formed by the superimposition of three blue, red and green images originating from three monochrome tubes 32b, 32r, 32v via an optical assembly 31. The blue image comes from the tube 32b through a relay objective 34a and by reflection on a dichroic filter 35a. The axis common to the tube 32b and to the objective 34a and the axis of the image I ′ is orthogonal, the dichroic filter 35a being inclined at 45 to these two axes passing through their point of intersection. The red images and green are transported in common by the same relay objective 34b which is arranged in front of the dichroic filter 35a and whose axis is coincident with that of image I ′. The red image comes from the tube 32r and reaches the objective 34b through a lens 36a and after reflection on a dichroic filter 35D. The tube 32r and the lens 36a have the same axis orthogonal to that of the objective 34b, the dichroic filter 3 = S; being inclined at 450 by contribution to these two axes passing through their point of intersection Finally, the green image comes from the tube 32v and reaches the objectf 34b through a lens 36b and after having crossed the dichroic filter 35b, the tube 32v and the lens 36b being located on the axis of the objective 34b.

 The tubes 32D, 32r and 32v are identical, as are the relay objectives 3a and 34b and the lenses 36a and 36b. The latter have the function of presenting to relay objective 34b red and green images under the same conditions as that of presentation of the blue image to relay object 34a. The objectives 34a, 34b fulfill the same functions as those of the objective 24 described more with reference to FIG. 2.

 Thanks to this arrangement, it is possible to obtain a high definition color image by means of high definition monochrome small size tubes, and of reduced size objectives which reduces their costs. In addition, the monochrome tubes having by nature a brightness greater than that of the trichrome tubes, not only the definition of the image obtained is improved, but also its luninicity.

 An additional advantage linked to the use of relay lenses, according to the invention, lies in the possibility of increasing the lateral field by juxtaposition of images, that is to say by juxtaposition of similar sets comprising a color tube , a relay lens and a semi-reflective blade.

 FIGS. 4 and 5 illustrate such a device in which three color tubes 42a, 42b, 42c are associated respectively with three relay objectives 44a, 44b, 44e and three semi-reflecting plates 43a, 43b, 43c to form three images juxtaposed on the surface spherical mirror 40, the latter being in one piece or in several juxtaposed parts. In this example, the assembly is equivalent to the juxtaposition of three devices such as that illustrated in FIG. 2. The semi-reflective plates and the parallel axes of the different tube-objective assemblies are arranged so as to place three images exactly juxtaposed on the focal surface of the mirror 40.

Figure 5 shows the arrangement of the blades 43a, 43b, 43c seen from above; they form three axes of a pyramid whose apex is vertical to the observation point 0. The points M1, M2 and M3 are the points of intersection of the axes of the relay objects with the associated semi-reflecting plates; they are located equidistant from point 0.

 As a variant, for each tube-objective assembly of the device of FIGS. 4 and 5, a group formed of three monochrome tubes and of an associated optic may be substituted, as illustrated by FIG.

 Of course, other modifications and additions may be made to the embodiments described above of a device according to the invention without thereby departing from the protective framework defined by the appended claims.

Claims (4)

1. Device for the infinite return of a video image observed at a wide angle, in particular for the reproduction of the environment in a simulator, device comprising a spherical mirror (20;  30 ; 40) and a semi-reflecting plate (23; 33a, 33b, 33c 43a, 43b, 43c) intended to place in the focal surface of the mirror an image of the video image formed on a screen (22; 32b, 32r, 32v , 42a, 42b, 42c), characterized in that a relay lens (24; 34a, 34b; 44a, 44b, 44c) is placed between the screen and the semi-reflective plate to in particular enlarge the video image formed on the screen. 2. Device according to claim 1, characterized in that it comprises a plurality of screens (42a, 42b, 42c) each associated with a lens (44a ,. 44b, 44c; and a semi-reflecting plate (43a, 43b, 43c) individuals so as to place on the focal surface of the spherical mirror (40) several juxtaposed images. 3. Device according to any one of claims 1 and; 2, characterized in that the or each relay objective (24; 34a, 34b; 44a 44b, 44c) is arranged so as to transform the video image formed on the screen (32; 32b, 32r, 32v; 42a, 42b , 42c) into a spherical image placed on the spherical focal surface of the mirror (20, 30, 40) by means of the semi-reflective strip. 4. Device according to any one of claims 1 to 3, characterized in that it further comprises optical means (35a, 35b, 36a, 36b) for forming a color image by superposition of images of several real images formed on separate monochrome cathode ray tube screens (32b, 32r, 32v).