FR2630835A1 - Method of producing 3-D images and means for implementing the said method - Google Patents

Abstract

The present invention relates to methods and devices enabling images which give a 3-D impression to be produced without the need for individuals to wear accessories, such as suitable spectacles. The method according to the invention is essentially characterised in that it consists in producing, from a given scene, two, right 2 and left 1, stereoscopic primary images, in cutting these two primary images into longitudinal strips 4, 3 having substantially parallel edges and substantially constant and equal widths, in composing a composite single secondary image 5 by juxtaposing alternately one strip of each right and left primary image, and in optically masking 11, 12, 13, 14, in this composite secondary image 5, respectively the strips 7 of the right primary image for the individual's left eye and the strips 6 of the left primary image for his right eye. Application to the production of a device making it possible to have the perception of 3 D with stereoscopic video images without it being necessary to use accessories such as suitable spectacles.

Description

Method for making images
with an impression of relief
and means for implementing said method
The present invention relates to the methods of producing images giving an impression of relief according to the principle of stereoscopy essentially intended to be observed by individuals having two eyes separated by a given distance, the application of these methods to the formation of video images giving an impression of relief according to the same principle, and the devices making it possible to implement these methods.

 It is well known that an individual, with the help of his two eyes, can see the elements which surround him with the perception of the relief.

On the other hand, it is very difficult to obtain reproductions by images which give this perception of relief. There is indeed a process, that of the holographic technique, which makes it possible to obtain an image having a relief. This technique is undoubtedly perfected but has a major drawback, its very high cost price, because its implementation requires the use of coherent light sources like lasers of high power, these types of blazers being very bulky instruments and of a high cost price. Another disadvantage is that the field size of the images obtained is very small.

 Other procedures lead to the perception of relief. One of them is the stereoscopic process. This essentially consists in obtaining two images of a given scene taken from two points distant from each other by a distance substantially equal to that which separates the two axes of vision of an individual, in other terms the distance between the axes of his two eyes, an average distance of 65 mm. An individual will perceive the relief of the given scene by simultaneously observing the two images obtained, provided that these are perfectly discriminated, so that his left eye can only see the image taken at the point on the left, and his eye right, the image taken at the point on the right.

 This discrimination is mainly done by the polarization of light, or by the use of colors. In all cases, it obliges the observer to wear appropriate glasses at all times, but effectively allows representations of images with perception of relief, as well in the domain of the static image as in that of cinematography or of videography.

 However, this technique has never really reached a significant level of popularization, mainly due to the constraint imposed on spectators wearing glasses. This condition limits the applications of this technique by preventing, for example, its use in the field of active communication, such as advertising. In fact, this type of communication is only interesting if it can reach any individual anywhere and at any time, even impromptu. It is then quite understandable, in this case, that the observers may not have the possibility of wearing on them the appropriate type of glasses.

 The object of the present invention is to implement a method for producing images presenting an impression of relief for an individual having two vision eyes separated by a given base distance, according to the principle of stereoscopy, which does not require the wearing, by this individual, of special glasses, and which is more of an easy and inexpensive implementation. The present invention also aims, by way of application, to implement such a method in the field of producing videographic images. The present invention also aims to provide a device for implementing said method in the field of videography.

More specifically, the subject of the present invention is a method of producing images giving an impression of relief for an individual having two left and right eyes separated by a given base distance, characterized in that it consists
to produce, from a given scene, two stereoscopic primary images called "right" and "left",
cutting the two said primary images into longitudinal strips substantially with parallel edges and of substantially constant and equal widths,
to compose a single composite secondary image alternately juxtaposing a strip of each right and left primary image, and
to optically obscure, in this so-called composite secondary image, the bands of the right primary image for the individual's left eye and the bands of the left primary image for his right eye, respectively.

The present invention also relates to a method of producing a videographic image giving an impression of relief according to the principle of stereoscopy for an individual having two left and right eyes separated by a given base distance, characterized in that it consists :
videographing a given scene in the form of two stereoscopic videographic primary images called "right" and "left",
delivering primary video signals respectively representative of the two said right and left primary images,
electronically cutting said primary video signals into sequences of video signals of substantially equal duration,
in recombining said sequences of video signals so as to successively and alternately juxtapose the signals corresponding respectively to the two said left and right primary images, in order to obtain composite secondary videographic signals,
transforming said composite secondary videographic signals into a composite secondary videographic image into alternating videographic tapes, and
to obscure, for the right eye of the individual, the videographic tapes corresponding to the left primary image, and, for the left eye of the individual, the videographic tapes corresponding to the right primary image.

The present invention also relates to a device making it possible to implement the method for producing videographic images giving an impression of relief according to the principle of stereoscopy for an individual having two left and right eyes separated by a given base distance. , characterized by the fact that it comprises
means for forming, of a given scene, two primary stereoscopic videographic images from two left and right points distant substantially from said given base distance, and delivering two sets of primary video signals corresponding respectively to the two left and right primary images ,
means for cutting the two said sets of primary video signals into sequential signals of substantially equal durations,
means for successively and alternately adding said sequential signals belonging respectively to the two sets of primary video signals, and delivering a composite secondary video signal representative of a composite secondary video image formed by alternating videographic tapes belonging respectively to the two primary left and right video images ,
means for transforming said composite secondary video signal into a visible image forming said composite secondary image, and
means for obscuring the optical path towards, respectively, the two left and right eyes of the individual, bands corresponding respectively to the two primary video images, right and left.

Other characteristics and advantages of the present invention will appear during the following description given with reference to the drawings annexed by way of illustration, but in no way limiting, in which
FIGS. 1, 2, 3, 4 and 5 represent diagrams making it possible to explain the implementation of the method according to the invention,
FIG. 6 represents a diagram making it possible to explain why an individual can observe an image giving an impression of relief without the aid of an accessory such as a pair of suitable glasses,
FIG. 7 represents another diagram making it possible to explain another mode of implementation of the method according to the invention in agreement with the diagrams according to FIGS. 1 to 6,
FIG. 8 represents a block diagram of a device for taking videographic images making it possible to implement the method of producing images presenting an impression of relief according to the principle of stereoscopy,
FIGS. 9, 10 and 11 represent three diagrams making it possible to explain part of the operation of the device according to FIG. 8,
FIG. 12 represents a block diagram of a structural detail of the device in accordance with FIG. 8,
FIG. 13 represents a diagram making it possible to explain the operation of the device according to FIGS. 8 to 12, and
FIG. 14 represents an example of a particular application of the device according to FIGS. 8 to 13.

 Overall, the figures appended to this description represent different forms of implementation, both for the methods according to the invention and for the device making it possible to implement these methods. However, for the sake of simplification and better understanding, it is specified that the same references designate elements of the same function, whatever the figures on which they appear.

 Returning more particularly to FIGS. 1 to 6, these represent diagrams making it possible to explain the implementation of a method according to the invention for the production of images giving an impression of relief, for an individual having two eyes. left and right separated, in known manner, by a determined distance substantially equal to 65 mm> which the technicians designate by the name of "base". The process implemented uses the principle, in its primary function, of stereoscopy which, being well known, will not be recalled or developed here.

 According to the method according to the invention, one begins by taking, from a given scene, two stereoscopic views 1, 2 like those which would be seen respectively by the two left and right eyes of an individual. These two images 1, 2 of the same scene are respectively represented G and D in, respectively, the two figures 1 and 2. They are obtained in different ways, according to the mode of restitution envisaged for their observation by the individual.

However, for the sake of clarity, it is assumed that these two images are obtained, for example, by two cameras the optical axes of which are taken at a distance from each other substantially equal to the base of vision of the individual, or by a single device, but with a double optical path making it possible to give, with a single objective, the two left and right images of the stereoscopy.

These two images 1, 2 are then cut into longitudinal strips 3, 4 with substantially parallel edges and of a constant width advantageously equal for all. Then, these bands 3, 4 are arranged together to form a secondary composite image 5 as shown in FIG. 3. This composite secondary image 5 is produced so that a band 3 of a primary image, for example the left 1 , is inserted between two bands 4 of the other primary image, the straight line 2, advantageously taking one out of two of these bands. It is therefore formed, FIG. 3, of a juxtaposition of the longitudinal 6, 7 (g, d, g, d, ...) alternately of the priwa image, left and the primary image right, in the same order as that of their formation, so that the bands follow the progression 21d, 12g, 23d, 14g, 25d, 16g,
This juxtaposition of bands then gives a secondary image of the same dimension as one or the other of the left or right primary images.

 In the case where these primary images are taken on photographic paper, the strips are, for example, glued next to each other on any support. When this composite secondary image is thus produced, THERE IS! associates means 8 making it possible to obtain an optical occultation respectively of the bands of the right primary image for the left eye of the individual and of the banks of the left primary image for his right eye.

 Figures 4 and 5 show an example of means 8 for obtaining this optical occultation of the different bands.

These means consist of a weft 21 of alternately opaque 13 and transparent strips 12 12 of the same width as the strips 6, 7 of the composite secondary image 5. This screen ll is, in this embodiment, positioned in front of the composite secondary image 5, that is to say between the face 15 of this image opposite to that which is stuck on the support defined above and the possible observer.

 This frame 11 is placed at a distance from the composite secondary image of the order of magnitude, for example, of the width of the longitudinal strips, parallel to the composite secondary image 5 and in such a way that the strips 12 of this frame, in a projection along the axis of vision of the individual, are projected onto the composite secondary image 5 while being offset, with respect to the longitudinal bands of the composite secondary image, by a value equal to the half-width of these longitudinal bands, as shown in FIG. 4. In other words, the advantageously orthogonal projection of each band of the frame is arranged astride "on two consecutive bands 6, 7 of the composite secondary image and each of its edges is equal distance from the dividing line between these two consecutive bands.

 Of course, the composite secondary image and the frame are usually defined in parallel planes. However, it is not unthinkable to be able to produce, for various reasons, secondary images and corresponding screens on curved surfaces, for example cylindrical slightly concave or convex.

FIG. 6 represents an advantageous embodiment of the method according to the invention explained above. This embodiment comprises a matrix 16 of a solid transparent material, advantageously with two faces 17, 18 parallel, for example a glass plate or a semi-rigid gelatin or the like and which may even have a certain flexibility of deformation. The thickness of this matrix will be determined experimentally, but is generally substantially of the order of magnitude of the width of the longitudinal strips and of the strips of the frame, its most distant face 18 from a possible observer 19 being called rear face " and the other 17 being called front face
On the rear face 18 of this matrix 16 are arranged, for example by gluing with a transparent material, the longitudinal bands 6, 7 of the left primary images 1 and arotte 2, taking only one in two and alternating them so as to obtain a composite secondary image 5 as described above.

 On the face avRSr 17 of the matrix, is arranged, for example also by bonding with a transparent material, the frame 11 of bands 12 alternately opaque 13 and transparent 14. This frame can be obtained by bonding, on the front face of the matrix in transparent material, opaque bands of width defined above and distant by the same width, so that in orthogonal projection on the quarry face, they are "straddling two long long bands, successive ldfoales, conne defined ci -before.

 This achievement is interesting because it makes it possible to present a unitary product which can be easily exploited commercially and which does not present any vision problem for an individual 19 who, if only by simple "reflex", will automatically tend to be placed in relation to the planes of the composite secondary image and of the frame, so that its axis of vision is perpendicular to them, its left eye 10 seeing only the bands 6 coming from the left primary image 1 and its right eye 10 not seeing that the bands 7 coming from the right primary image 2, as defined above. Everything: the individual observer can thus, without special glasses, perceive the relief of the scene recorded in two primary stereoscopic images.

 1t is rependent to specify that, according to the method of producing the composite secondary image described above, the two primary left and right images that the individual sees are not complete, since one band out of two is missing. However, the human brain is so e4it that it easily extrapolates the incomplete information provided by the eyes, to reconstruct the images as a whole. the same is true for the two left and right stereoscopic primary images.

 There is therefore a slight difference in the result of a vision of a stereoscopic image of a scene according to the present invention compared to that with, in particular, a pair of suitable glasses: in the case of the invention, the assessment light is slightly lower, but very little, since the glasses themselves absorb some of the light energy.

 In what has been described above, the frame 11 is arranged between the composite secondary image 5 of the scene to be perceived with an impression of relief and the observer 19, and the image is observed by reflection, since the bands constituting the the composite secondary image were cut out of the primary images drawn on paper. Indeed, in this case, the light of illumination of the composite secondary image strikes the various grains of this image on paper located on one of its faces, and these grains then play the role of diffusers on the same side of this face than the one from which the incident light comes.

 However, according to another characteristic of the present invention, it is also possible to obtain composite secondary images 5 from photographs taken using the so-called "slide" technique. As illustrated in FIG. 7, the observation of the scene is then made by the transmitted light, that is to say that the incident light 20 strikes one of the faces 21 of the image 5, and all the grains from this image transmit light by diffracting it at the output of the other face 22, on the other side with respect to that from which the incident light comes. It is therefore advantageous to have the composite secondary image 5 between the frame 11 and the observer 19.

 In this case, the composite secondary image 5 is constituted, in the same way, of bands of primary images alternately left and right, but produced in a material capable of transmitting light such as that used in the technique of slides. The strips are arranged on a support such as a matrix as described above, but on its front face, while the frame of alternately opaque and transparent strips is arranged on its quarry face. The lighting light, for example given by lamps 23 of the neon tube or similar type, is then placed behind the frame 11 relative to the observer 19 who will thus perceive the scene by diffracted light.

 This technique therefore allows the observer 19 to preferentially see, on the composite secondary image 5, with his left eye 10, the bands 3, 6 of the left primary image 1 more illuminated than the bands 4, 7 of the right primary image 2, and vice versa for his right eye 9. In other words, he preferentially receives, on his left eye, the left primary image with a much more intense luminosity than the right primary image, and conversely for his right eye . His brain receives the "signals" produced by his two eyes and selects the brightest images himself. The observer 19 thus sees two left and right images, as in the technique of stereoscopic vision, according to the well-known principle making it possible to perceive the impression of relief.

 The technique described above finds a particularly advantageous application for the perception of relief vision in the field of video, always without the spectators needing to use additional elements or accessories, and of course only if these spectators have two normal eyes separated from a given base such as that defined above.

 FIG. 8 represents the block diagram of a block diagram of a device for implementing the method according to the invention allowing the viewing of videographic images with the perception of the relief, without the need to wear accessories such as appropriate glasses. This figure shows the basic functional elements of a device according to the invention, for producing videographic images presenting an impression of relief. This device essentially comprises means 30 for forming two primary video images called "right" and "left", capable of delivering at their outputs video signals VD and VG respectively representative of each right and left primary image. These two video signals are processed and mixed by addition in an electronic processing member 31, an advantageous structure of which will be given below, in order to produce at output 32, as explained below, an identical composite secondary video signal VGD.S, in its function, in the composite secondary image 5 described above with reference to FIGS. 1 to S. This signal VGD.S is then applied to the control input 33 of a display of the video screen type 34, for example that which constitutes the picture tube of a television.

In front 35 of the television video screen, is arranged the frame 11 whose definition and function have been explained above. This frame 11 may be static, consisting of a plate of opaque material of very small thickness so that it can be well stretched on the outer face 35 of the screen, on the side of the spectators. This frame can also be of the dynamic type, that is to say for example constituted by deposits of different layers next to each other and the opacity of which can be controlled by any means, for example electronic, such as liquid crystal.In this case, depending on the processing of video signals
VGD.S, the tube supply circuit will further comprise output means 36 connected to each liquid crystal band 37 of the dynamic frame 11 to correlatively control, as explained below, the selective appearance of a band opaque on two, whether, as the case may be, the chronologically even or odd numbered bands.

 FIG. 9 represents an advantageous embodiment of the means 30 making it possible to take, from a given scene 40, two so-called right and left video images to give birth, as mentioned above, to two primary video signals VD and VG. In this advantageous embodiment, a camera composed of two objectives 41, 42 is used for two signal analyzes equivalent to two coupled cameras, the optical axes 43, 44 of which are taken are separated from the so-called basic distance "defined in the preamble to this description.

The objectives used can advantageously be anamorphic in X with a multiplying coefficient equal to 1/2. With this characteristic, two right 45 and left 46 video images are obtained, the X dimensions of which are halved, while the Y dimensions are retained. The orientations referenced X and
There are those usually used for locating in a plane, respectively along the horizontal and the vertical. FIG. 10 gives a representation of these two images obtained from scene 40 illustrated by way of example in FIG. 9. it should be noted that this characteristic of the objectives can also be used in the case of the formation of images according to the method described with reference to FIGS. 1 to 5.

 As a result, a single basic camera is advantageously used for electronics, but with a double lens delivering, for each line signal L n, L n + l, L n + 2, ... conventional in video representation , a first video signal VD 47 with half a line length corresponding to the right image 45, and a second video signal VG 48 with a half line length corresponding to the left image 46.

 It should be noted that, in the focal plane 49, images are inverted by the optical lenses. However, for the sake of simplification in FIG. 10, the right and left images have been represented once again inverted like those which are obtained after rectification, for example by means of an afocal system 50.

 The composition of the two juxtaposed images represented in FIG. 10 leads to a video image of the same dimensions in X and in Y as a video image reproduced by a conventional video screen. Furthermore, the direction of the video analysis of these two images has been represented, FIG. 9, on block 51 which is the converter of optical images into line video signals, so that this analysis begins with that of the image. right.

 The lower part of FIG. 10 represents the continuation of the video signals VD and VG successively obtained at the output of the camera during the analysis, along a same line, of the two images right 45 and left 46. The demonstration below will be given opposite this single line, the extension to the set of all the lines constituting a video image posing no difficulty for a person skilled in the art.

 The processing member 31 defined above is shown in more detail in FIG. 12 which gives a very advantageous embodiment thereof, especially from the technological point of view, having regard to the nature of the components currently placed on the market, and which are essentially based on digital circuits, rather than on analog circuits for which it is necessary to obtain delay lines with durations too short for them to be currently achievable with all the desired safety and viability.

The electronic processing unit 31 has an input 60 successively receiving the video signals VD and VG obtained by the analysis of each line between two synchronization tops each separating the analysis from two consecutive video lines. As shown in Figure 10, it is assumed that the first part of the line corresponds to the right primary video image and that the second part corresponds to the left primary image. Under these conditions, the signals
VD arrive, in time, before the VG signals.

 The device therefore includes a switch delay circuit 61 comprising, from an input 62 receiving the two signals VD and VG, a switch 63 controllable by a control input 64 and the two outputs 65, 66 of which are connected, one directly to a first output 67 of the switch delay circuit 61 and the other, via a delay line 68 of a value equal to that of the transmission time of the two signals VD and VG, to a second output 69 of this switch delay circuit.

 The control input 64 of the switch delay circuit 61 is for example connected to a clock 70 delivering periodic pulses allowing the switching defined as a function of the line scanning frequency, for example 18.5 z in the case of television currently commonly used, especially of the type "mainstream. '. In addition, the switch 63 is controlled so that, because the video signal VD arrives first, it is directed to the delay line 68. The two video signals VD and VG appear simultaneously on outputs 69 and 67 respectively, as shown in FIG. 13.

 The two first 67 and second 69 outputs of this switch delay circuit are respectively connected to two chains of series type circuits 71 and 72 comprising at input an input amplifier 73, 74 respectively of analog video signals VG and VD The output 75 , 76 of each amplifier 73, 74 is connected to the input 77, 78 of an analog to digital converter 79, 80 whose output 81, 82 is connected to the inputs 83, 84 of a memory 85, 86 whose capacity is determined to preserve, in the form of digital information with good definition, the video signals corresponding respectively to the analysis of the left video image and the right video image. In addition, the content of these memories can be interrogated by addressing in a given chronological order, for example, by a clock 87 whose output 88 is connected to the input 89, 90 for controlling interrogation of each memory 85, 86 This clock also makes it possible to synchronize the two converters 79, 80.

 The two output assemblies 87, 88 of the two memories 85, 86 are respectively connected to the two supply inputs 91, 92 of a mixing circuit 93 by successive additions of portions of signals in digital form, so as to obtain a succession of these portions of signals by time slots respectively determined by the coding of the digital signals stored in the two memories corresponding to the two video primary images, in order to obtain at the output of the mixing circuit by addition a video signal comprising, for a line of definition for the video screen for which it is intended, portions of successive video signals 101, 102, 103, ..., FIG. 13, corresponding in electronic form to the bands of the two primary images as defined above. of these portions of video signals corresponding respectively to the signals VD and VG is obtained at output 94 of the mixing circuit 93, to form the composite secondary video signal VGD.S corresponding to a video line between two synchronization signals 104 and 105.

 Returning to the example given above for a mainstream video, the duration of each signal portion 101, 102, 103, ... is 74 ns. As a result, the video screen will comprise approximately 730 bands, or 365 for each of the two right and left video signals. We therefore obtain a composite video secondary image equivalent to the composite secondary image 5 such as that which has been defined, in particular, with reference to FIGS. 1 to 4.

 It should be noted that, due to the formation of the two right and left images each equal, in the direction x, to half the width of the screen, adding them strip by strip belonging alternately to each of them, forming a line video signal representative of a composite secondary image occupying the entire width of the screen. Of course, this mixing is carried out by adding digital data, which is an implementation technique which poses no difficulty, this addition of successive signals being able to be done for example in counters supplied by the contents of memories 85 > 86 perfectly addressed.

 Consequently, the output 94 of the addition mixing circuit 93 delivers between two line synchronization signals 104, 105 line video signals VGD.S, FIG. 13, in digital form. However, since most televisions can only be powered by analog signals, the output 94 of the mixing circuit 93 is advantageously connected to the input 95 of a digital analog converter 96 whose output 97 can be connected to a television of the conventional type, as represented functionally in FIG. 8.

 As mentioned above, the demonstration has been made for one line, but it can be transposed to the set of all the lines of the definition of a television video image which generally comprises 625, or a number of this order. of greatness.

 With this system, the television therefore displays on the inner face 98 of its screen 35, FIG. 8, a composite secondary video image having the same definition as that which was given with reference to FIGS. 1 to 6. Indeed) this transparent screen , because generally made of glass, and of thickness 99, constitutes the matrix defined above which makes it possible to maintain the frame 11 between the secondary composite video image and the eyes of the viewer.

 This frame comprises a number of alternately opaque and transparent bands equal to the number of bands of the secondary image but arranged to be astride "on them and, for example, the transparent bands are obtained by removing material in an opaque plate. Returning to the example given above, the number of these opaque and transparent bands will be, for each type, of 365. The width of these bands is of course a function of the horizontal dimension of the screen of the television, if "1" is the width of this screen, each band will therefore have a width equal to 1/730, that is, for televisions commonly used in the public, a width of the order of 0.7 to 0.8 mm.

 This frame must be placed on the front of the screen and, the bands making it up, generally substantially vertical, but possibly oblique in certain cases, are advantageously held at their ends by two rigid supports which allow them to be stretched and press, for example, against the front of the screen so that there is an overlap of the strips of the composite secondary video image as described above.

 It is necessary that this frame is perfectly well positioned and that it can even possibly be moved to adjust its positioning as a function of the television broadcast. In this case, it is advantageous to make a frame of an electrostatic material which, in known manner, is attracted by a running television screen.

This material can be, for example, plastic.

 However, as mentioned above, the frame can be of the dynamic type, for example based on liquid crystals, the opacity or transparency of which can be controlled by any electronic signal produced in synchronization with the video signals. This implementation does not pose any particular difficulty for a person skilled in the art will not be described more fully here.

 FIG. 14 represents a possible use of the method described above for a representation by a television set from images prerecorded in a video recorder 140. The complete device therefore comprises a camera 141 capable of delivering at its output 142 representative primary video signals of the two right and left images, as described above. This camera output can then be connected to the input 133 of a processing member 131 identical, for example, to the member 31 described with reference to FIG. 12, the output 132 of which is connected to an input 143 of the video recorder 140 which records the mixed images as described above. In this case, the output 144 of the video recorder 140 can then be connected directly to the input 151 of any television set 150. It is also possible to connect the output 142 of the camera 141 to the input 143 of this same video recorder to record, without mixing, the two right and left images. In this case, in order to be able to view the images, the output 144 of the video recorder is connected to the input 151 of the television set, for example through the same processing device 131, in order to be able to obtain the composite secondary video images on the screen 152 of the television 150.

Claims (16)

 1. Method for producing images giving an impression of relief for an individual having two left and right eyes separated by a given base distance, characterized in that it consists  to produce, from a given scene, two stereoscopic primary images called "right" and "left",  cutting the two said primary images into longitudinal strips substantially with parallel edges and of substantially constant and equal widths,  to compose a single “composite” secondary image by alternately juxtaposing a longitudinal strip of each primary image. right and left, and  to occult- optically, in this so-called composite secondary image, respectively the bands of the right primary image for the individual's left eye and the bands of the left primary image for his right eye.  2. Method according to claim l, characterized in that the production of the two stereoscopic primary images called "right and" left "of a given scene is obtained by two focusing photographic objectives, whose optical axes are located at a distance one of the other substantially equal to said base of vision of the individual.  3. Method according to one of claims 1 and 2> characterized in that the production of said composite secondary image (5) is obtained by juxtaposing, alternately, a plurality of bands (3) of the primary image left (1) and a plurality of bands (4) of the right primary image (2), in the same order as that of their formation, so that the bands follow a determined progress (21d, 12g, 23d, 14g, 25d, 16g, ...).  4. Method according to one of claims 1 to 3, characterized in that the optical occultation in said composite secondary image, respectively bands of the right primary image for the left eye of the individual and bands of the left primary image for his right eye is obtained by a screen (11) of alternately opaque (13) and transparent (14) bands (12) of the same width as the bands (6, 7) of the composite secondary image (5).  5. Method according to claim 4, characterized in that said frame (11) is positioned between said composite secondary image (5) and said individual observer (19).  6. Method according to claim 5, characterized in that said frame (11) is placed parallel to the composite secondary image (5) and so that said strips (12) of this frame, in a projection along the axis of vision of the individual, are projected onto the composite secondary image (5) while being offset, with respect to the longitudinal bands of the composite secondary image (5), by a value equal to the half-width of these bands longitudinal (6,7).  7. Method according to one of claims 4 to 6, characterized in that between said frame (11) and said secondary image is disposed a matrix (16), said matrix being made of a transparent material.  8. Method according to one of the preceding claims, characterized in that said secondary image (5) is obtained by taking only one out of two of said bands respectively of said left (1) and right (2) primary images.  9. Method according to claim 4, characterized in that said composite secondary image (5) is formed from primary images called "slides", this said composite secondary image (5) being disposed between said frame (11) and the individual observer (19), the light for illuminating said secondary image being placed behind said frame (11) relative to the observer (19).  10. Method for producing videographic images on a video screen giving an impression of relief according to the principle of stereoscopy for an individual having two left and right eyes separated by a given base distance, characterized in that it consists  videographing a given scene in the form of two stereoscopic videographic primary images called "right" and "left",  to deliver primary video signals which are respectfully representative of the two said right and left primary images,  at. electronically cutting said primary geographical signals into sequences of video signals of substantially equal duration,  in recombining said sequences of video signals so as to juxtapose successively and alternately the signals corresponding respectively to the two said left and right primary images, in order to obtain composite secondary videographic signals,  transforming said composite secondary videographic signals into a composite secondary videographic image into alternating videographic tapes, and  optically obscuring, for the right eye of the individual, the videotapes corresponding to the left primary image, and, for the left eye of the individual, the videotapes corresponding to the right primary image.  11. Device for implementing the method according to claim 10 for producing videographic images giving an impression of relief according to the principle of stereoscopy for an individual having two left and right eyes separated by a given base distance, characterized by the fact that it includes  means for forming, of a given scene, two primary stereoscopic videographic images from two left and right points distant substantially from said given basic vision distance, and delivering two sets of primary video signals corresponding respectively to the two left primary images and right,  means for cutting the two said sets of primary video signals into sequential video signals of substantially equal durations,  means for successively adding said sequential signals alternately belonging to the two sets of primary video signals, and delivering a secondary composite video signal representative of a composite secondary video image formed of alternating bands belonging respectively to the two primary left and right video images,  means for transforming said. visible secondary composite video signal forming said composite secondary image, and  means for obscuring the optical path towards, respectively, the two left and right eyes of the individual, light bands corresponding respectively to the right primary video image and to the left primary video image.  12. Device according to claim 11, characterized in that said means for forming, of a given scene, two primary stereoscopic videographic images from two left and right points distant substantially from said given base distance, and delivering two sets of primary video signals corresponding respectively to the two left and right primary images comprise a video camera (30) comprising two objectives (41,42) whose optical axes (43,44) are separated from said base, said objectives being anamorphic in X d 'A multiplier coefficient equal to 1/2 and in Y of a coefficient equal to 1, said orientations referenced X and Y defining a location in a plane following respectively the horizontal and the vertical.  13. Device according to claim 12, characterized in that said means for cutting the two said sets of primary video signals into sequential signals of substantially equal durations comprise, from an input (60,62) adapted to receive successively the video signals from said camera (30), a switch delay circuit (61) comprising a switch (63) controllable by a control input (64) and the two outputs (65,66) of which are connected, one directly to a first output (67) of the switch delay circuit (61) and the other, via a delay line (68) dt a value equal to that of the transmission time of a half line of video signals, to a second output (69) of said switch delay circuit.  14. Device according to claim 13, characterized in that said means for successively adding said sequential signals alternately belonging to the two sets of primary video signals, and delivering a composite secondary video signal representative of a composite secondary video image formed by alternating bands belonging respectively to the two left and right video primary images consist of two series circuit chains (71,72) whose inputs are respectively connected to the two outputs (67,69) of said switch delay circuit (61), each chain comprising the minus an analog to digital converter (79,80), a memory (85,86) whose input (83,84) is connected to the output (81,82) of said converter and whose capacity is determined to preserve in the form of digital information the video signals corresponding respectively to the analysis of the left video image and the right video image, and a mixing circuit by addit successive ions (93) whose two inputs (91,92) are respectively connected to the outputs of the two said memories (85,86).  15. Device according to one of claims 11 to 14, characterized in that said means for transforming said secondary video signal into a visible image forming said composite secondary image in alternating bands are constituted by a video tube (34) with a screen display (35) made of a transparent material.  16. Device according to claim 15, characterized in that said means for obscuring the optical path towards, respectively, the two left and right eyes of the individual, light bands corresponding respectively to the right video image and to left video image, are constituted by a frame (il) of alternately transparent and opaque bands disposed on the external face of said screen (35).