FR2650407A1 - Method and devices for recording images which can be perceived in three dimensions and application of such a method - Google Patents

Abstract

The camera Oc, Ec is held practically immobile with respect to the object and perceptible relative dimensional variations in the various planes in space are caused, in the region of the recorded image, by variations in optical means Oz located in front of the camera.

Description

METHOD AND DEVICES FOR RECORDING PERCEPIABLE IMAGES IN THREE DIMENSIONS AND APPLICATION OF SUCH A METHOD.

 The invention relates to a method for recording images using a camera, film camera or video camera or the like, images whose succession, when restitutioqgermet and observers their perception in three dimensions.

 The practice of cinema and television shows that it is possible to perceive, in three dimensions, projected images in two dimensions, provided that certain conditions are respected, during the shooting.

 We will cite, as characteristic examples, first of all the historical sequence of one of the Lumière brothers' first films "Arrival of the train at La Ciotat", a sequence that terrified the audience during the appearance of the machine literally bursting the screen. Some time later, a method, still used and designated by the expression "trans-trav", makes it possible to obtain this impression of the three dimensions: it consists of subjecting the camera to a frontal or lateral displacement, with variation of the focal lengths of its purpose. Closer to home, some landscapes recorded from a helicopter in flight, allow a remarkable perception of space. Finally, more recently, shots made in macrophotography give, figures or animated objects of various movements, a good restitution of three dinensions.

In these examples, apparently of different natures, it is found that the shots are taken either from a fixed camera, with movements of subjects or objects, with respect to it; either with movements of the camera relative to objects, themselves can be fixed or animated. Now, these different processes lead ultimately to obtain moving images, the relative dimensions of which vary according to the relative distances of the objects and the camera, variations to be perceived by the observers. These characteristics, which appear at the basis of the perception of relief from the processes currently known and comparable to those we have recalled, led the authors, following their experiences, to the following conclusions:
if we call it the dimension of the image of an object of dimension 0 located at the distance D1 of the recording camera and i2 that of a second object of the same dimension 0 but located at a distance D2 m D1 of the camera, the ratio of these dimensions, at the recording time tl, has a certain value
i1
- = K
i2 different from the unit.After a few seconds of the variation of the images, by variation of the relative distances object-camera, by any process, the report in question becomes at time t2: i'1
K '= - i.2
The experiments of the authors show that, under these conditions, the perception of the third dimension can be obtained, during the examination of the recorded sequences, only for minimum or maximum determined perceptible values of the ratios such as:
K
V =;
K 'these ratios becoming smaller or larger than the next unit that the relative object / camera movements are approximations or removals.

For example, after a sequence of about ten seconds, sequence registering in particular relative object / camera comparisons, the more or less good conditions of perception of the relief are approximately delimited by the observers between thresholds such as:
1>V> 0.90: adaptation to the perception of the relief
0.90>V> 0.60: perception of relief.

 If it is, on the contrary, relative distances objects / camera, the above values become inverse of the previous ones and are between unity and 1.70.

 These experiments have led the authors to develop a process that takes into account the results obtained and, in addition, allows the simplification of current procedures and greater efficiency.

 According to the invention, the method has the following characteristics: the objective of the camera, kept fixed, not directly records the images of the outdoor space according to the usual practice, but more precisely the images of this space previously reduced to a scale significantly less than unity. This reduction is obtained from a zoom lens placed in front of the camera lens and along its optical axis; the zoom is also kept fixed. The objective of the camera, thus records the spatial images generated by the zoom, spatial images located on both sides of its focus image plane. For example, the object space included between a first plane located at two meters of the camera and a background located at ten meters is brought back, by a zoom focal length of one hundred millimeters, to an image space of four millimeters in thickness that the lens of the camera thus records. For such a recording, the latter has a focal distance significantly less than the zoom focal length: for example 5 m / m.

 The relative movements objects / camera, responsible for the possibilities of perception of the third dimension, are replaced by the relative movements between the spatial images, created on either side of the image plane of focus of the zoom, and the objective of the camera: these relative movements are obtained by causing dimensional variations of the image space of the zoom, by variation of the focal lengths of the latter during the shooting.

 Moreover, in order to maintain the constancy of the depths of field of the recorded images, in spite of the variations of the distances of the spatial images with respect to the objective of the camera kept fixed, in synchronism with the variations of the focal lengths of the zoom, variations of opening of a diaphragm disposed on the optical path of the device.

The invention consists, apart from the arrangements set out above, in certain other arrangements, of which it will be more explicitly mentioned below, with regard to the particular embodiments described, with reference to the attached drawings, but which are not in any way whatsoever. limiting:
- fig. 1 is a diagram of an optical assembly, according to the invention; showing in longitudinal section a zoom arranged at the front of the camera and, following it, the camera's own objective, the upper part of the figure relating to the minimum zoom focal length, the lower part at its maximum focal length ;
- fig. 2 is the enlargement of a part of FIG. 1, showing the detail of the formation of the spatial images given by the zoom and the images given by the lens of the camera;
- fig. 3 is the representative graph of a zoom-in shot, giving, as a function of time, the zoom focal length, the aperture of the camera aperture and its resulting focal lengths, and the possibilities spatial perception that can be expected;
- fig. 4 is the same graph as Figure 3, but with zoomed out;
- fig. 5 is a longitudinal section of the device realizing the synchronism of zoom focal length variations with those of the openings of the diaphragm;
- fig. 6 is a longitudinal section of an improvement made to the device of FIG.

 The present description relates to a non-limiting example of the invention, for example relating to a cinematographic film camera 8 m (m, or video camera or the like, and whose optical assembly is schematized, in cross-section, at the figure 1.

 The optical assembly is constituted by two distinct objectives of the same optical axis: the first arranged at the front is a zoom lens Oz with variable focal lengths between a minimum of 30 m / m (Fig. 1 upper) and a maximum of 100m / m (lower figure 1); the second, a 0c lens with a constant focal length of 5 m / m. Recall that a zoom lens generally includes: - a group before focusing (figured in Op), - a basic objective (Ob), - an afocal system with variable magnification (the other divergent and converging groups of zoom.O ).

 In the example cited, the variation of the focal lengths is obtained by lateral translation of the divergent groups.

 It should also be remembered that normal quality zooms retain both a constant brightness and a constant focus plane even after pre-focusing and regardless of focal length variations. The latter defines, for traditional cameras equipped with a zoom, the recording image plane, constant position plan by construction and destination. Thus, after choosing an object plane and adjusting sound / image from the front group Op, this plane occupies a fixed position figured according to P'oPo.

The camera's own objective Oc has the following characteristics: its focal length is reduced to 5 mlm in the example described; similarly, its thickness is limited to 12 m / m. was chosen from an anastigmat lens
three lenses, including two convergent framing a third divergent.

Obtained from lanthanum glasses, it allows an acceptable quality of images despite a relatively small thickness. Its position is such that its upstream hump is juxtaposed to the downstream hump of the basic zoom lens.

 The diaphragm of the device, according to the example described, is the own diaphragm of the zoom. n is Di (fig 1). This is a traditional iris diaphragm whose operation operates as it will be specified, in synchronism with zoom focal lengths.

 The camera portion shown in Ec corresponds to the location generally reserved for the recording of images on cinematographic film, magnetic medium or other, depending on the type of camera.

In order to clarify the explanations that follow, FIG. 2 is an enlargement of the useful part of the camera lens, as to the formation of the images. The objective of the camera is schematized in the reduced form of a dioptric system centered between its two main planes P1 and
P2 and its two foci F'c and Fc, form allowing a precise representation of the different images given by the two objectives Oz and Oc.

 The zooming plan P'oPo is located at a distance Uo from the downstream hump of its basic objective Ob, a distance of 19 m / m in the example described. Thus, the external objects located at the distance Cd of the camera, distance corresponding to that of the focus, are located in the plane P'oPo. Those in front of or behind this distance Do have their image in front of or behind P'Op0; respectively for example in r2 or I'l for recordings made with the minimum focal length of the zoom and at 12 and li with its maximum focal length - and between these images for the intermediate planes.

 According to these provisions, the real spatial images given by the zoom, such as r2 and Il, for example, are for the purpose of the camera virtual images. The latter gives, in view of its position, real spatial images such as I '2 and II, in the same sense as I'2 and II (the march of the corresponding rays is drawn in dashed lines in Figure 2). But the images such as i'2 and it are spatial images and the camera records, in fact, on its recording plane P'ePe, images i'2 and he who are the projections on this plan. These are arranged in a normal position, like i'2 and it, for a traditional shooting.

rapport des grandeurs des images enregistrées par la caméra o à celles des objets situés à la distance D de cette dernière d : distance d'une image spatiale donnée par l'objectif de la caméra au
foyer image de cet objectif
Fz/Fc : distances focales du zoom (variables entre F'2 et F2) et de l'objectif
de la caméra
U : distance du plan image de mise au point du zoom P'oPo au foyer
amont Fc de l'objectif de la caméra x : distance d'une image spatiale donnée par le zoom à son plan image
de mise au point.We give, hereinafter, two characteristic relations of the assembly, according to the example described, which will, in the following, a better understanding of the process. These relations result, according to Gauss notation, from the geometry of the montage:

ratio of the magnitudes of the images recorded by the camera o to those of the objects located at the distance D of the latter d: distance of a spatial image given by the objective of the camera to
focus image of this goal
Fz / Fc: focal lengths of the zoom (variables between F'2 and F2) and the objective
from the camera
U: distance from the zoom focus image plane P'oPo to focus
upstream Fc of the lens of the camera x: distance of a spatial image given by the zoom at its image plane
of focus.

Relation (2) makes it possible to specify the positioning of the device: the upstream hump of the camera lens is brought into near-coincidence with the downstream hump of the basic objective of the zoom. Under these conditions, the object focus Fc (Fig. 2) of the camera lens is below this hump at a distance of 4 m / m. The distance U from the zoom focus plane P'oPo to this focus is thus 23 m / m, given the Uo distance of 19 m / m as previously indicated. By the way, the distance d from the recording plan
P'ePe of the camera in the home The image of its objective is 1.1 m / m, the distance of the P'oPo and P'ePe planes being 4.13 m / m.

It should be noted that the example described is a test prototype and that in particular the surfaces in the presence of the bumps of the two objectives of the device
(zoom and camera) are not optically satisfactory. In one embodiment in progress, these surfaces are constituted by two parallel planes more satisfactory, but which require a choice, if not a special manufacture of the extreme lenses of these objectives.

Regarding the relation fol), it allows first of all to verify that the camera, according to the example described, is a camera for images of
8 m / m: from this relation, we have the value of the focal length Fr resulting from the conjunction of Fz and Fc, namely:
Ft Fe
Fr =
which gives, for variations of Fz between 30 and 100 m / m, corresponding variations of Fr between 6.5 and 22 m / m, values applicable to a camera of 8 m / m.

This relationship also makes it possible to control whether, indeed, the camera, according to the example, is capable of recording perceptible images in the three dimensions. We summarize the conditions previously defined to obtain this result:
By calling V the ratio of relative dimensional variations, between the beginning and the end of a zoom, images of two objects of equivalent size but different distances from the camera, we must have:
0.90>V> 0.60 if it is a zoom in,
1.10 <V <1.70 if it is a zoom out.

The knowledge of the ratio as i / o given by the relation (1), makes it possible to determine the values of V from the optical characteristics of a camera, according to the present device. To zoom in, we find, as a first approximation:

Fz: maximum focal length of the zoom in the event that it is at least three times larger than the minimum focal length,
#Fz = Fz - F2 '(difference of the maximum and minimum focal lengths),
Do: distance from focus plane to camera,
D2: distance from the foreground,
D1: distance from the background,
U: distance from the zoom focus image plane to the upstream focal point of the camera lens,
Focus: focal length of the lens of the camera.

 For a zoom out V becomes K / K ', as indicated previously.

 The relation (1) is thus in the form of a product of two fractions: the first, close to unity if AFz is small in front of the distance from the first plane to the camera. The second, on the contrary, deviates more or less from the unit, according to the importance of z before (U - Fe), a fraction thus characterizing the possibilities of perception of space.

From the optical and dimensional characteristics of the example cited, the values of V are as follows: 1 / For D0 = 4m, D2 = 2m and D1 ->&alpha;
V varies from 1 to 0.77 for zooming in (30-100m / m) and 1 to 1.30 for zooming out (100/30 m / m)
20 / For the same values of Do and D2, but for D1 set at 10rn
V varies from 1 to 0.83 for zooming in and from 1 to 1.20 for zooming out
These values of V show that the camera, according to the device, is capable of recording perceptible images in the three-dimensions.

 Examination of relation (3) shows, moreover, that this possibility could be improved by slightly increasing the value of Fc with respect to U. n also shows that it is possible to predict camera formats such as 16, 35 m / m and over, without any other difficulties than the realization of the 8 m / m format of the present example.

However, besides the possible combinations of U and Fc, the quality of the images made, as to the possibility of their perception in space, also results from the characteristics of the two objectives of which the camera is equipped: its own and that of the zoom , objectives whose conjunction gives the resulting focal length Fr. It is from Fr that the images are more or less well perceived by the observers. However, experience shows that, for there to be perception of the third dimension, it is necessary that the images are sufficiently defined. This condition can only be fulfilled if the first and the rearward planes specified by the relation (3) , characterizing the possibilities of perception of space, are none other than the limits of the field depths perceptible by the observers, limits given by the basic relation which we recall below:

 Do is the focus distance.

 D1 / D2, the perceptible limit distances of the rear and foregrounds.

 n, the opening of the diaphragm of the lens of shooting, here of focal Fr.

 K the sharpness tolerance.

 A relation which shows, in particular, that, for given n and K, the depths of fields are all the weaker as the focal length is higher, a characteristic which reduces, according to this hypothesis, the perceptible differences between the first and the rear planes . Under these conditions, the zoom magnifications contribute to a weakening of the possibilities of perception of the third dimension.

 To avoid this disadvantage, according to the invention, the constancy of the depth of field is maintained by acting on the aperture of the diaphragm of the lens, in synchronism with the variations of the focal lengths of the latter: thus, when Fr increases (with the increases of Fz), n increases and vice versa. Experience shows, moreover, that it is not essential to observe a rigorous parallelism between the two variations. Indeed, by causing a decrease in illumination, the retinal separation limit of the observer increases, which increases the sharpness tolerance. Finally, the action on n triggers a parallel action on K and it is each of the factors n and K that intervene separately to increase the product nK.

This is what the experiment seems to show since the variations of the diaphragm can take place between more restricted limits than the only calculation of n as a function of F. However, to limit the value of n, the duration of the zoom is sufficiently long:
It can be seen, in fact, that this minimum duration varies from a few seconds to ten seconds, depending on the speed of movement of the subject, its initial illumination, its coloration and also according to the result sought by the director.

Figures 3 and 4 give some results obtained with the camera described in this example:
Figure 3 is the representation of a zoom in performed in a time of nine seconds. In abscissa, the times and ordinate are the main characteristics of the camera, as well as the spatial perception possibilities that result:
In dashed lines, - in the lower part of the graph, zoom focal lengths that start at Fz = 30 m / m and end at Fz = 100 m / m.

 Similarly and above, the variation of the openings of the diaphragm (n) which vary from the maximum aperture F: 2.8 to end at a minimum aperture of F: 8.

 These two simultaneous variations are linear with time.

 At the bottom, in dashed lines, the variation of the resulting focal length Fr, according to the invention: the focal length Fr thus varies from the minimum possible of 6.5 m / m to a maximum of 22 m / m.

 At the top. Figure the hatched spindle delimiting the possibilities of spatial perception V.

 Since this is a zoom in, the values of V must be between the unit and the minimum values of 0.90 and 0.60. The two examples given in full lines, the first with foreground to 2m and background to the, the second with foreground also to 2m and background to 10m, are actually included inside this time zone. The perception of space is correct from the first seconds of examination and continues until the end of the zoom. Note that the representative curves of V are virtually linear with time.

Figure 4 is a depiction of a zoom out on views identical to the previous ones The focal lengths of the zoom go down from 100 to 30m / m, while the openings of the diaphragm increase from F: 8 to
F: 2.8.

 Here, as it is a zoom out, the representative time zone of V varies from unity to values between 1.10 and 1.70. The two curves drawn in solid lines are actually included in this zone. There is also a correct spatial perception. As before, the variations of V are close to a linear variation with time.

These experiments have shown, moreover, that the variations of illumination do not affect the qualities of the images: they pass virtually unnoticed for unsuspecting observers. This observation, quite surprising, is explained by the fact that it is a juxtaposition of two variations (illumination and image size) operating in opposite directions:
When the illumination decreases and so that the possibilities of retinal separation decrease, the simultaneous increase of the dimensions of images overcomes this disadvantage and thus preserves the possibilities of normal vision. These opposing variations erase their individual effects and there remains for the observer only a global perception of a relief landscape that is close to him.

 On the other hand, when the illumination, however, believes that the dimensions of images decrease, the same phenomenon occurs but in the opposite direction: the increase in illumination overcomes the loss of retinal finesse resulting from the dimensional decrease of the images.

The observer finally perceives a landscape in relief that moves away from him.

 We describe, in the following, the technical means provided to obtain the synchronism of the variations of the focal lengths of the zoom and the opening of the diaphragm.

 With regard to the focal lengths, the current cameras are generally equipped with automatic devices allowing the desired variations of the focal lengths of the zoom, in connection with the recording of the images. It is therefore necessary to adapt existing arrangements to an additional function allowing parallel variations of the diaphragm according to the invention.

 We recall the means generally adopted to achieve the automaticity of focal length variations: it is a question, starting from afocal systems with variable magnification such as, for example, the group of lenses A'B '(fig. bring the latter to AR (lower fig.1) or vice versa.

This translation is most often carried out as shown schematically in FIG. 5:
The groups of lenses A 'and B' being integral with each other by means of rigid rods such as 1 for example, allowing the movements of the groups only laterally and along the general optical axis of the zoom, a part 2 forming a threaded nut, integral with this system, causes the lateral displacements of these groups by means of a threaded shaft 3.

The latter, controlled by a motor 4, integral with the camera, is engaged by the same thread in the room 2. It is understood that the rotation of the motor 4 thus causes the displacement of 2 and therefore that of the groups A 'and B 'compared to other zoom lenses. Depending on the direction of rotation of the motor, you can either zoom in or zoom out. The motor, usually electric, powered by batteries or accumulators, is equipped with automatic controls and stops from traditional transistorized electronic assemblies.

 The focal length variations thus obtained by the rotation of the motor, at constant speed, are linear with time. Furthermore, the arrangement of parts such as 2, 3 and 4 close to the basic zoom lens Ob (FIG 1) are also close to its diaphragm. The tree 3 is used to make the opening variations of the latter which will thus be linear with time. We indicate below, by way of non-limiting example, the means applied to obtain this result.

 We first summarize the principle of mounting an iris diaphragm: it consists of small slats between two rings, one fixed and the other mobile. On the first, can rotate each of the movable slats, respectively about an axis, each axis being at the vertices of a regular polygon around the perimeter of the fixed ring. The second ring, movable around the axis of the diaphragm, -control the movements of the slats, thus causing the desired opening variations.

 Figure 5 shows a sectional view of the movable ring controlling the opening of the diaphragm. This ring is, in view of the arrangements made, near the shaft 3 controlled by the motor 4. To obtain the rotation of 5, its periphery is lined with a rubber band or relatively flexible plastic material, coming from contact with a ring 6 mounted on the motor shaft 3. The contact surface of this ring is provided with flats to promote adhesion with the movable ring. Thus, the rotation of the motor causes the rotation of the latter and thus the variation of opening of the diaphragm in synchronism with the variation of zoom focal lengths.

The arrangements are such that they make it possible to obtain the desired synchronism from the single rotation of the motor unit 3. It is indeed possible to provide for:
1 / the direction of the screw thread traces on 3, in relation to the movements of A'B 'towards AB and the direction of rotation of the movable ring 5;
2 the value of this thread to obtain the desired amplitudes of displacements of A'B 'towards AB, as well as the value of the diameter of the control shaft, in relation to that of the moving ring 5, so that the latter performs only one turn, or a fraction of a turn, during the lateral displacement of the afocal group of the zoom.

 An improvement has been made to this device. That described above allows only maximum or minimum aperture openings of the diaphragm with those focal lengths. However, experience has shown that, depending on the characteristics of the shooting (possible speed of the objects, their illumination, their coloring or special effects sought), it was useful to have maximum or minimum values of variable aperture of the diaphragm, according to the needs of the shooting. This improvement, according to the invention, is shown schematically by way of non-limiting example in FIG.

 The latter is a cross section of the movable ring of the diaphragm of the camera, movable ring close to the motor shaft 3 controlled by the motor 4, as has been said above, but modified according to the improvement: on the motor shaft 3 is provided a cylinder 7 whose rotation is controlled by it, but this cylinder can further slide (before starting the engine) along its longitudinal axis, a few millimeters to the left or to the right. The cylinder 7 itself comprises three rings of different diameters 8, 9 and 10. The latter, spaced apart from each other by a distance equal to their thickness, are lined at their peripheral surface with flats, as previously mentioned. In view of these, the diaphragm opening control ring 5 is itself provided with peripheral rings 11, 12 and 13 of different diameters, in inverse ratio to those of the rings 8, 9 and 10 and having at their around a relatively soft surface as previously indicated.

 According to these arrangements, when the motor ring 9 is, for example, in contact with the ring 12, the rotation of the motor causes the opening or closing of the diaphragm with a certain speed V. On the other hand, if it has been previously put, by sliding to the left of the cylinder 7, the ring 8 facing the ring 11, the speed of variation of aperture of the diaphragm will be greater than V, given the different ratio of the diameters of the rings in contact; and conversely, if the cylinder 7 has been brought to the right to ensure the contact of the rings 10 and 13. Thus, the device makes it possible, by prior adjustment of the position of the cylinder 7, to obtain three different speeds of the variations of opening of the diaphragm with respect to zoom focal length variations.

 The three possibilities offered appear in sufficient numbers for the needs of traditional practice. It is however possible to obtain a larger number by increasing the number of rings. Furthermore, for intermediate positions of the rings in presence, it is also possible, as shown in Figure 6, to completely separate the diaphragm of the zoom variations, the diaphragm remaining in these conditions in a fixed position during the taking of views.

 The present invention, which relates, by way of non-limiting example, to an 8-megapixel camera, is transferable, as a device adaptable to film, video or similar cameras, to any camera, whatever the format. . The characteristic relationships of the device described can be generalized to any other device, according to the invention: in particular, it is possible to proceed with the recording of the spatial images given by the zoom, as real images and not as virtual images. , as in the example described, the method and the relations which define it remain applicable, with the signs near. Thus, the arrangements described concerning the realization of an optical trans-work, with constant depth of field with camera fixity, are obviously transposable to specialized cameras, transpositions therefore forming part of the invention.

Claims (6)

REVENDICAIIONS  1. Method for recording images using a camera (cinematographic camera or video camera or the like) images whose succession, during the restitution, allows the observers their perception in the third dimension, characterized by the the fact that we keep the camera almost immobile and that its objective records the spatial images that gives, from the external space, a zoom arranged in front of the lens of the camera and according to its optical axis, spatial images located on both sides. other of the zoom focus image plane.  2. Method according to claim 1, characterized in that the focal lengths of the zoom vary during the shooting and the zoom, like the camera lens, remain fixed during the latter.  3. A method according to claims 1 and 2 characterized in that it causes, during the shooting and in synchronism with the zoom focal length variations, opening variations of a diaphragm placed on the path Optical device.  4. Device according to claims 1, 2 and 3 characterized in that the zoom placed at the front of the camera lens and along its optical axis is sufficiently close to the latter so that the real spatial images it gives, for the purpose of the camera, virtual images, so that the latter objective gives real images, directly recordable by the camera in the usual conditions.  5. Device according to claims 1, 2 and 3 characterized in that the mechanical means 5 and 6 are adapted to ensure, from the shaft 3 driven by the motor 4 of the automatic control device variations of the zoom focal lengths. , the variations of aperture of the diaphragm, in synchronism with those of the focal lengths of the zoom.  6. Device according to claims 1, 2, 3, and 5 characterized in that the mechanical means 7, 8, 9, 10, 11, 12 and 13, mounted from the shaft 3, are adapted to ensure, according to the needs of the shooting, at least three different modes of synchronism between the variations of the focal lengths of the zoom and those of the openings of the diaphragm.