DE1948334A1 - Holographic camera with variable recording angle - Google Patents

Description

1348334

Patent attorney

Dfpl.-ln .. -., -. BdGtZ IL 410-14.949P 9/24/1969

Dipl.-Ing. Limprecht

Munich 22, Stelnsciorfstr. 10

Commissariat a! ^ Energie Atomique, Paris (France)

Holographic camera with variable angle of view

The invention relates to an extremely short exposure camera, in particular a camera based on the holographic Recording with a variable recording angle is based.

The extremely short exposure cameras currently most frequently used produce a real image a photographic plate, e.g. B. the rotating mirror cameras and the electronic cameras.

In the former, the image of the object is projected onto a number of lenses with the help of a rotating mirror, which are arranged on the scope of a loan and generate one image at a time on the film. The performance

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The limitations of such cameras are primarily due to technical factors. It is impossible to increase the speed of the mirror indefinitely because the mirror can deform and even crack. For this reason, opening times of less than 100 nsec can hardly be achieved. These cameras also have the disadvantage of a rather weak light intensity due to the small opening angle of the beams. They also need a lot of additional devices (pump, compressed air source, shut-off devices, etc.), which make the rotating mirror cameras complex and unwieldy. After all, it is difficult to synchronize them with the processes to be examined with an accuracy of better than 1 / U see.

A first group of electronic cameras is formed by cameras with "biplanar tubes, which are essentially only very fast shutters. They allow opening times of 1 nsec and even 300 psec. Their number of lines is relatively small, but the contrast factor is relatively ¹ Disadvantageously, they can only produce a single image per experiment, so that they can only be used for the investigation of reproducible processes.

A second group of electronic cameras is formed by the cameras with a deflection tube. These allow multiple images to be recorded during the same experiment, the technology allows This tube opening times of a few in the order of magnitudes nsec only with reduced image quality. Also is the available diameter of the photocathode the tube is no larger than 30 mm, which severely limits the information capacity · On the other hand, its resolution is im

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generally sufficient, their bulkiness small, and their Synchronization does not lead to any particular difficulties.

When developing cameras that record multiple images in good quality as possible To allow faster follow-up, use is made of holography, which not only provides a lot more information can be obtained, but also applied to a single plate and then several records are spatially separated during the evaluation of the recording.

Likewise, holographic cameras have been developed in which between the recording of the various Holograms on a single plate take place mechanical displacements relative to the position of the object to the photographic plate and to the reference beam, so as to separate the different images for playback is enabled. It is already known to pivot the plate about an axis perpendicular to it, so that the images are distributed around the reference beam for reproduction. Furthermore, it is already known to use the reference beam to pivot about an axis defined by the object and the center of the plate, the reproduced images are distributed around the reference beam as in the previous case. After all, it is already known to change the angle between the direction of the scanning beam and that of the reference beams so asu that for Playback the images can be seen in different directions.

Even if the well-known cameras for recording

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are suitable for relatively slow processes, d. H. for processes with a duration of more than 100 nsec, If this limit is not reached, mechanical shifts are the same as with rotating mirror cameras excluded during the experiment.

The invention is therefore based on the object of specifying an extremely short exposure holographic camera, based on a change in the angle of view between two successive records are based »

A holographic camera with a variable angle of view, with a holographic assembly that consists of consists of a laser and a deflector to generate two different beams from the light emitted by the laser and to interfere with them on the same photographic plate after the one beam hits has illuminated stationary object, the image of which is to be recorded, is characterized according to the invention by means of an optical shutter that blocks out a very short pulse of light from at least one of the beams, and by an optical device for decomposition arranged on the path of the masked light pulse of the light pulse into a sequence of partial pulses that are spatially offset and delayed from one another, and to project the partial pulses at a variable angle of incidence according to the type of output beam the object or the photographic plate.

The invention is further developed in that the closure in front of the deflection element on the path of the laser emitted output beams is arranged so that it comes out fades out a very short pulse from the output beam,

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and that the optical devices are identical to the Paths of the two light pulses separated by the deflecting element are arranged and each of these light pulses in break down a sequence of partial pulses, each partial pulse generated from the first light pulse being synchronized to a partial pulse generated from the second.

The invention is explained in more detail with reference to the drawing, in the single figure of which an embodiment of the camera according to the invention is shown «

A ruby laser 1, the coherent light pulse rsit a duration of about 30 nssc »is an optical one Shutter 2 assigned to a Kerr or Pockels cell, which interrupts these pulses so that pulses with a duration of about 1 nsec are generated.

The emitted light is split into two beams with opposite directions by two mirrors 3 which are inclined at 45 °. The two rays then each fall simultaneously at an angle of incidence θ on a glass plate h with parallel surfaces, the surface of which is semi-transparent and the rear surface of which is totally or completely reflected. As a result of successive reflections of the light on these two surfaces, several pulses are obtained from a single initial pulse, which emerge in parallel directions which are offset from one another by a distance e and mutually by a time interval l / v, i.e. the quotient of the light inside the Glass plate traversed path to its speed of propagation in this plate are delayed.

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Part of the light beam falling at point A onto the surface of incidence of the glass plate k is reflected, creating a first pulse J, while the other part of this light beam is refracted and completely reflected at point B on the reflective rear surface and falls back onto the incident surface at point C. . Part of this light is now refracted and forms the second pulse II, which is parallel to the first but offset by a distance e and by a time interval; is emitted delayed, while the other part of the incident light beam at point C is reflected, again passes through the glass plate, is reflected at point D on the rear surface and falls back on the incident surface at point E to generate a third pulse IXl, which by is offset by a distance e to the second and is also delayed by a time interval "*" with respect to this.

This process is repeated so that two trains of pulses of coherent light are obtained, in pairs are synchronized, and of which the one as scanning beams and the other as reference beams. for receiving a sequence of different holograms can be used.

It can be seen that when a sequence of rays should be obtained that transport the same energy, which is essential for the production of identically exposed images a certain reflection coefficient is desirable there is a must for the reflections on the Surface of incidence in points A, C, E etc. different is. In addition, the plate must have a considerable thickness; if z. B.! »Pulse with a mutual time

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If a delay of 1 nsec is to be obtained, the plate must be about 10 cm thick. However, panels with parallel surfaces that meet these requirements are difficult to manufacture. Therefore, according to the invention, so-called "Piano ^M plates" are preferably used, the incident surface of which is formed by adjacent semitransparent plates and the rear side by a flat mirror which runs parallel to the plate. In this way, the reflection coefficients and refractive indices of the plates can easily be selected be that an equal distribution of energy between the various successive light beams is achieved.

A "step" deflector 5, which is located in the path of the ^{beams emitted by each of the "Piano n} -PlM.tten" and preferably consists of a glass plate cut so that a superposition of several prisms is achieved, serves to deflect the beams successively depending on their emission, on the one hand, on a transparent object 6, the image of which is to be recorded, with each beam coming from one of the plates, and, on the other hand, on a photographic plate, each beam coming from the other plate Light that has passed through the object 6 is captured by a lens 8 which creates an image on a frosted glass pane 9. The partial light beams scattered by the frosted glass pane 9 interfere with the reference beam in order to generate a hologram on the photographic plate 7. The glass plate forming the step deflector 5 can be divided into two identical parts.

In this way one sequence interferes one after the other

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1348334

of scanning and reference beams on the photograph! Plate and record completely different holograms there, because not only the reference beam is on the photographic plate has a different angle of incidence, but also the object 6 each time through the scanning beam is seen from a different angle "

The first hologram is recorded by the pair of pulses I: the reference beam has an angle of incidence i on the photographic plate 7, while the object is seen by the scanning beam at an angle i *. The second hologram is then recorded after a time interval * by the pair of pulses II * The angle of incidence of the reference beam is now i ₂ , and the object is seen at an angle i ·.

This process continues so that one in a camera recording on the same photographic Plate, which is in a precisely static holder, allows one from a single initial impulse Obtains a sequence of holograms that are easily adapted to be reproduced in very different ways. This can be made by flash lighting the holographic recording, e.g. B. with the help of a gas laser. the Different images are played back one after the other by changing the angle of incidence of the playback beam to the Recording is changed. It can therefore be seen that the camera according to the invention enables the observation of very much fast processes and that with a very high number of lines or resolution. So you can follow 10 Obtain holograms separated by 1 neec, each corresponding to an aperture of about 1 neec.

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It can also be seen that the camera has been modified in this way can be that the optical shutter is no longer in front of the deflecting member 3 »but on the path of the reference beam (or the scanning beam) is located.

In this case, the uninterrupted beam no longer falls on a plate with parallel surfaces, but directly on the object (or the photographic plate). Although the reference beam (or the scanning beam) now have a constant slope and can be present for the entire duration of the recording sequence you always get a sequence of different holograms because the object is now at a different angle each sampling pulse is seen (or each reference pulse on the photographic plate at a different angle falls).

With such a design, however, coherent wave trains must be used that are long enough to to extend over the entire duration of the episode, this condition not being the symmetrical one shown Arrangement required.

The invention can also be modified in other ways compared to the illustrated embodiment. In the embodiment explained above, the holographic recording is carried out by transmitting light with a Diffusing means made, the object being a phase object, d. H. no «weakening of the Light, but only changes the wavefronts. However, the holographic recording can also be used in other Way -be made, z. B. about reflections, when the object is not translucent.

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Claims (1)

Claims (JV Holographic camera with variable recording angle, with a holographic assembly consisting of a laser and a deflector to generate two different beams from the light emitted by the laser and to allow them to interfere on the same photographic plate after the one Beam has illuminated a stationary object whose image is to be recorded, characterized by an optical shutter (2) which fades out a very short light pulse from at least one of the beams, and by an optical device (4) arranged on the path of the masked light pulse for Breakdown of the light pulse into a sequence of partial pulses (i, II, Hl), which are spatially offset and delayed from one another, and for the projection of the partial pulses at a variable angle of incidence (i * _f i '₂; i- »i ₂ ) according to the type of Output beam s on the object (6) or the phot © graphic plate (7). 2 · Holographic camera according to claim 1, characterized in that the shutter (2) is arranged in front of the deflection element (3) on the path of the output beam emitted by the laser (1) so that it fades out a very short pulse from the output beam, and that the optical devices (4) are arranged identically on the paths of the two light pulses separated by the deflecting element (3) and split each of these light pulses into a sequence of partial pulses (I ₉ II, III), each partial pulse generated from the first light pulse being synchronized to a partial pulse generated from the second is " 009815/1609 3. Holographic camera according to claim 2, characterized in that the optical devices have a glass plate (k) with parallel surfaces, of which the incident surface is semi-transparent and the other surface is reflective, and a deflection device (5) with a variable deflection angle, which are in the path of the light emitted by the glass plate. k. Holographic camera according to claim 3 »characterized in that the glass plate (4) is formed on its incidence surface by adjacent plates which have different reflection coefficients in order to achieve an equal distribution of energy between the different light beams emitted by the glass plate {k) , and that the other Surface is formed by a flat mirror that runs parallel to the plate. 5. Holographic camera according to claim 3 »characterized in that the deflection device (5) at least is formed by a glass plate, which is a superposition of several prisms. 009815/1609 Blank page