DE683987C - Screen for recording and displaying spatial images from several lens networks - Google Patents

Description

Screen for recording and displaying spatial images from several lens networks The invention is based on a screen for recording and displaying spatial images from several lens networks. The invention aims to achieve a simple Embodiment of such screens, which avoids the use of a ground glass, to be used in the same way for both shooting and projection is and in both cases without any particular visual difficulties Spatial images. Also to the use of Fresnel lenses instead of a focusing screen the invention is not bound. According to the invention, the screen is designed in such a way that that the optical elements of a first system of these networks virtual images of the Generate the exit pupil of the objective providing the spatial image and that these are virtual Images are captured through a second lens mesh system that captures those of the midpoints Light rays emanating from these virtual images in one on the main optical axis of the entire optical system located point can converge.

For example, the drawing illustrates several embodiments of screens according to the invention in a schematic representation.

Fig. R shows a screen consisting of two or three grids in a section along a plane which is the optical axis of one with the screen cooperating lens. Fig.2 gives a practical embodiment of a screen with two grids in a section on the same plane as Fig. I again. Fig. 3 shows in section a screen with three Grids, one of which is dispersive, and Fig. q. leaves a practical embodiment recognize this umbrella in the cut. In all figures there is an association; technical the Lines of light rays made the perfectly permissible approximation that the Main points of the optical elements in alignment with simple lenses with their optical Coincide in the middle.

In Fig. I, O is a projection lens or the lens of the first Chamber of a receiving apparatus containing several chambers. The screen E consists from a first grid El, which consists of diverging lenses of the focal length f1 is composed, and in the upper part of Fig. i from a second grid E2 from converging lenses with a focal length f2. If ei and e2 are the optical centers of two corresponding optical elements of these two grid networks El, E2, the element with the center ei results in a virtual image il the Exit pupil of the objective O in the plane II, which is with the focal plane of the Grid El practically covers. This image behaves like a real object with reference to the element of the grid network E'2, and a real picture of it is generated by this element in the plane H, which the optimal viewing zone for the three-dimensional relief image of the Objective O projected onto this screen E or one projected thereon Relief recording is. Zone H can also be the entrance pupil of the objective of the second chamber or one of the objectives of the second chamber or of several be second chambers, which are supplied by the objective O of a first chamber Receives relief image and records it on a halftone film.

The plane II is the closer to the focal plane of the grid E, and at the same time the focal plane of the network El, the smaller the size of the focal lengths f1 and f2 of the networks El and E2 with respect to the distances between the lens O and the Zone H of screen E is. The divisions of the networks El and E 2 are from each other and different from the division of the pictures. and are derived from the location and the Distance of zone H and lens O.

In such a device, in which there is no more ground glass is, on the other hand, the optical elements of the grid have to be individually connected to each other to determine zone H. There is only one zone H where you can an observer or a lens of a second chamber under the most favorable conditions can provide if the nets have lenticular notches wrestled while one if the nets are separated by a matte screen, several adjacent zones H are retained. Dis' "Zone H extends in a plane perpendicular to the drawing of Fig.i. Direction You can see several viewers or several lenses from the second chamber in it Provide one above the other, if at least: one of the grid grids El and E2 made of cylindrical optical elements whose generators are perpendicular to the plane of the drawing.

In the lower part of Fig. I is between the two grids El and E2 shows a graduated convergent lens D of the Fresnel lens type. If one of the two outer networks El and E2 or each of them is cylindrical This third grid D can consist of cylindrical converging lenses consist of the same cross-section in the plane of the drawing as the Fresnel lens. This grid or this lens D has a focal length f, which is preferably a lot is greater than the focal lengths f1 and f2 of the grids El and E2, and results in a plane I'2 a single virtual image of the image for each optical element i '"which has been delivered by the corresponding optical element of the grid network E. is. This image i'2 is represented by a; a single element of the network E2 recorded to play it back in the H zone.

The Fig. I shows in particular in its upper part that the optical elements of the network El must be shielded very strongly, namely the more one moves away from the main optical axis of the objective 0. This is necessary in order to achieve that all elements of the two networks are individually connected to each other correspond in an optically correct manner, d. H. about any encroachment of one optical element of the network El outgoing light beam from this element exactly corresponding optical element of the network E2 to other optical elements of this To prevent network E2. This dimming can be achieved by using a suitable grid is connected to the network El.

Fig. 2 shows a screen provided with such a screening grille E with only two grids. 0 is again the projection lens or the lens the first chamber of a receiving apparatus containing a plurality of chambers, and H on the main optical axis of the objective O is also the optimal viewing zone in FIG or the place for the arrangement of objectives from second chambers. According to Fig. I is the focal length f2 of the network E. or the focal length f'2 of the network E ', greater than the focal length f i of the grid Ei. It follows that in Fig. I the angle ß or ß ', at that of the centers of the element of the grid E. from the virtual images il generated by the preceding network or networks or i 2 is generally smaller than the angle a at which the exit pupil of the objective 0 from the optical centers of the elements of the network El is seen from. This can be for practical use of this species be a shortage of umbrellas.

According to FIG. 2, this deficiency is remedied in that the optical elements of the two grid networks Ei and E2 are selected in such a way that the distances practically equal to the focal lengths f i and f 2 of these networks, which the optical centers ei and e2 from the virtual ones Separate images i1, are in a ratio to each other that exceeds the value i. The angle β can then appear larger than the angle α.

For this purpose, for example, the optical elements of the Network egg in the cross section passing through the plane of the drawing in FIG a negative meniscus with a convex surface directed towards the objective 0 and the cross-section of the optical elements of the network E2 has the shape of a positive Give meniscus with a convex surface also directed towards optic 0. It it then follows that the main points, which are considered to have the centers ei and e2 of this Systems are assumed to be united in two levels between the networks Ei and E2 in the reverse order as these can be provided, resulting in has that the angle ß is greater than the angle α.

These meniscus cross-sections of the optical elements of the networks are in Fig. A in dashed lines above and below that of each optical element used hatched indicated cross-sectional parts indicated. One also sees in this Fig. a, that in order to achieve the most correct transmission of the light beam the successive optical elements from one place to another in these Meniscus cross-sections are cropped in an ever-changing manner when one progresses from the center of the screen to its edges. The optical elements the center of the screen are coaxial with the two nets, and each is symmetrical trimmed to their common optical axis, which with the optical axis of the lens 0 coincides. This no longer applies to the immediately neighboring ones Elements, and the deviation of the used cross-sections of certain optical elements of the same network from the cross section of the central optical element of this The further away from this central element, the greater the network. The whole formation of one and the same network is symmetrical on both sides this middle optical element.

About the bundles of light that have passed through the individual elements of the network E. to prevent other optical elements of the network E2 such as that in this network dem relevant element of the network Ei to encounter the corresponding element, one must either the individual elements of the network Ei and E2 corresponding to one another through partition walls U bridge or, even simpler, near the network Ei and for example on the side of this network facing towards the objective 0, a grating T with opaque elements Arrange strips that properly distribute the light beam from one to the other Network guaranteed.

One can also look at the light intensity of the facility and the ratio act between the angles ß and a in an even more successful way, in the case of the dispersing system delivering the virtual images on the last network composed of a first collecting network and a second dispersing network. These two networks act to generate the virtual elementary images of the exit pupil of the lens together, and these images are taken individually through the collecting optical Elements of the third and final network added. One trained in this way and acting screen with three nets is shown in Fig. 3, in which he, E2 and E3 are the three grids that make up the screen E. The second Network E2, which lies between the other two networks, is solely dispersive. the optical centers ei, e2 and es belong to three corresponding optical centers Elements of these three networks. The element having the optical center ei of the collecting network Ei provides a first real image il of the exit pupil of the objective 0 in its focal plane II. This image becomes through the corresponding to it optical element of the second network E2, which is dispersive, received and behaves to this element like an object. This is due to this system of two optical elements of the networks Ei and E2 the resulting image is when the focal length f2 of the network E2 is sufficiently short, the virtual image lying in a plane I2 i2. This level is I2 the focal plane of the third and last network E3, which is collecting and gives an image H. Levels I, and 12 are related to the network E2 conjugates one another.

The Fig.4 shows how the light bundles are guided to them at a interfering overlap from one optical element of a network to another of the same network. According to FIG. 4, the optical elements have different networks in the plane of the drawing as in Fig. 2 with meniscus cross-sections thin or thick edges. The concave surfaces are the meniscus elements of the networks E1 and E2 and not, as in FIG. 2, their convex surfaces after the lens 0 directed so that the maximum opening of the optical elements of the network Ei and the minimum deflection of the light beams emanating from the networks Ei and E2 is reached, while the concave surfaces of the meniscus elements of the network E according to H are turned so that the optical centers of the plane 12 are approximated.

In the example given, the elementary images i2 are larger than the divisions of the networks E2 and E3, and consequently those adjacent to one another intervene Images i2 into one another geometrically, which is optically irrelevant because it is a question of virtual images and each of them only through a single optical one Element of the network E3 can be transmitted or made perceptible: One sees in this example also that no partition and no grating between the optical Elements of the three networks is required and the light efficiency is a maximum achieved.

For all the screens shown, screens without a focusing screen apply receives; in which the correct transmission of the light bundle from the lens 0 according to Zone H is guaranteed. The incidence pupil of one provided in zone H. Objective of a second chamber or the zone H serving as a viewing plane can as optically conjugated to the exit pupil of objective 0 via this type of screen be considered, for all arbitrary ratios of the angles ß and a and for any ratio of the distances between the objective 0 and the zone H from the outermost networks of such screens.

In contrast to this optically conjugate relationship between the Objective 0 and zone H can also be arranged in such a way that one is in the Screens of Figures 3 and q. the last collecting net leaving it out. With this modification is every light beam emanating from a point of the image i2 and the one corresponding to it optical element of the dispersing network E2 penetrated, no longer at the exit point this element of the network E2 a parallel light beam, as it is at 'the exit point of the collecting network E3, but there is a scattering of the light rays, which be significant and the luminous efficiency as well as the sharpness of the relief image can noticeably affect this type of screen. The application of this arrangement remains possible despite this and with this reservation.

Each network of screens according to the invention can consist of several components exist; where the curvature and other properties of the optical elements are chosen so that the generation of the images i, and i2 is improved.

Depending on the needs of the individual application; d. H. ever according to the conditions for the viewing of the on the screens according to the invention perceptible three-dimensional image or for its inclusion through lenses from second chambers can apply one or more of the nets of the umbrellas spherical optical elements and the others made of cylindrical optical elements be educated.

When photographing with apparatus with one or more second Chambers can have a vibrating pane of glass near the or in the zone H provided lenses or any other suitable means to use in known Way the formation of moirities by projection of the lenses facing Network of the screen E to the generally parallel or approximately parallel To prevent halftoning of the halftone film used for relief photography.

Claims (6)

PATENT CLAIMS: i. Screen for recording and reproducing spatial images from a plurality of lens networks, characterized in that the optical elements of a first system of these networks generate virtual images of the exit pupil of the objective providing the spatial image and that these virtual images are recorded by a second lens network system which uses the Light rays emanating from the centers of these virtual images converge in a point located on the main optical axis of the entire optical system. 2. umbrella according to claim i, characterized in that the virtual images through the optical elements of a the end Diverging lenses existing first network (El) generated and individually by the corresponding optical elements of one consisting of converging lenses second network (E2) are included, its division from the division of the first Network (El) different. is (Fig.z above). 3. Screen according to claim 2, characterized in that that between the two lens networks (El, E2) another lens network (D) is switched on is, the optical elements of which have the cross-section of a converging lens of the type Have Fresnel lens and which are individually made up of the optical elements of the first network (El) record emerging light bundles and these in turn individually according to the corresponding optical elements of the second network (E'2), without them on non-corresponding elements to spread over, forward and which thereby the through the optical elements the first network (El) generated virtual images enlarge (Fig.z below). q .. Screen according to claim 2, characterized in that a grid (T) with the first Network (El) is connected, which is a division different from the division of this network has and which the overlapping of the individual optical elements of the first network (E1) outgoing light bundles on these respectively not corresponding optical elements of the second network prevented (Fig. 2). 5. Screen according to claim z, 2 or q., characterized in that the optical centers of the elements of the two networks (El, E2) in parallel planes that are the reverse of the two networks (El, E2) follow one another, are located, and that the optical elements of this Networks (El, E2) different fractions of lenses of a particular, for one and the same network are always of the same type (Fig. 2). 6. Screen according to one of the claims r to 5, characterized in that the first dispersive network system consists of a collecting and a dispersing lens network (Ei, E2), their focal lengths are chosen so that the virtual images generated by this lens network system greatly enlarged by the effect of the dispersing lens network (E2) of the system appear (Fig. 3).