DE2701789B2 - Apparatus for recording a hologram of an object and for reconstructing the same with white light - Google Patents

Description

The invention relates to a device for recording a hologram from an object and to Reconstructing the same with white light according to the preamble of the patent claim.

According to the USt-BS 35 35 013 are with white light Reconstructable holographic frames known according to the US-PS 35 35 013 eic such a hologram is generated! That the object or the object from a point source of coherent light, for example a laser, is illuminated. The light scattered by the object is converted into a Formation of a real image of the object in focus Adjacent this image is a flat photographic, light-sensitive recording medium in a Arranged in the plane normal to the optical axis of the The recording medium is not only affected by the stray light from the object, but also illuminated by the light of an extended reference light source, this light being temporally coherent with the The point source of the coherent light is the object is imaged in the hologram plane and so a Image hologram generated The hologram is used to reproduce the hologram recorded in this way Illuminated by a non-stretched light source of incoherent light, de in relation to its spatial Coherence characteristics is different from the extended reference light source essentially coincides with the relative position of the reference light source, which this in relation to the Recording medium during the recording step has a three-dimensional image of the hologram recorded object is reproduced without the need for a source of illumination for reproduction would be, which is identical to the reference light source. However, there is the disadvantage that when im If there is a hologram defect, the defect interferes with the scattered light and the formation of a clearly reproduced image.

Another disadvantage of the US-PS process 35 35 013 lies in the fact that the reproduced picture the The size of the image recorded on the hologram plate and therefore its dimensions is limited. The method described there therefore only develops its advantages in the case of reduced images, since

s then the image points of the recorded object are very close to the holographic plate.

In the known from US-PS 3625584 Device, a hologram is first reversed with the help of a cylinder optic in one dimension

to shown reduced from this first picture with the help of a second lens, a second, laterally correct image produced, which then as Cinema film can be used, the cylinder lenses used there are arranged in such a way that their

is focal points coincide. Major disadvantage the device described there is that for

Production of an enlarged image the three-dimensional

Sional information is lost in one direction

The registration is based on the task of a

To provide apparatus for recording a hologram, so that by means of the hologram a stereoscopic image using white light can be reconstructed, in which a deterioration of the image due to the interference of any errors present in the hologram are eliminated with the illuminating beams, so that a clear image is always obtained, the hologram being said to be capable of a larger image reproduce as corresponds to its own size

According to the invention. this task is carried out by the im Characteristics of the claim mentioned features solved

In the following description, an exemplary embodiment is shown in detail with reference to the drawings explained Here shows or show

Fig. 1 in an explanatory perspective view an optical focusing system,

Fi g. 2 in a schematic representation of a system for Generation of holograms uitd

3A-3C are explanatory views showing the Illustrate the reconstruction of the holograms.

The basic principle of the optical system for generating a hologram according to the invention is hereinafter initially with reference to FIG. 1 explained, in which a holographic plane 2 is shown, on which a hologram of the object point 1 is to be formed. A pair of cylindrical lenses 3a and 3b are arranged between the object point 1 and the holographic plane 2, each of which only emits light in one Bundle direction, that is, one-way. These lenses are arranged so that the directions in which they focus light are perpendicular to each other. The cylindrical lens 3a creates a real image of the object point 1 in the vertical direction (direction of the K-axis) on the holographic level 2. The interference between this light and an illuminating reference light 4 (laser light) in the YZ plane creates a normal hologram. In relation to the transverse direction, the cylindrical lens 3b initially generates a one-way virtual or Inset S of the object point 1 with respect to the transverse direction (direction of the X-axis) at a point, which is slightly in front of the holographic level 2. Accordingly, it will be simultaneous with the formation of a one-way real image of the object point 1 relative to the vertical direction on the holographic Level 2 generates a hologram, which from the interference between the reference light 4 and the diverging wavefront from the virtual image 5

of the object point I with respect to the transverse direction results. This means that the hologram which on the holographic plane 2 is a vertical image diagram showing parallax in Having transverse direction

The principle described above with regard to the formation of a hologram * »with respect to an object point applies in exactly the same way to the formation of a hologranua with respect to a solid body, since a solid can be viewed as a collection of object points.

An embodiment of a system for recording a hologram according to the above The principle described is in FIG. 2 reproduced.

As Fig.2 shows, a laser beam 21, which is from a laser 20 comes through a beam splitter 22 into an object illumination beam 23 and a reference beam The object illuminating beam 23 is reflected by mirrors 23 and 26 and then across a lens (or a mirror) 29 is projected onto an object 10. The reference beam 24 is through a Mirror 27 is reflected and then via a mirror (or lens) 30 onto a holographic plate 2 projected A diffusion plate 31 can be arranged between the lens 29 and the object 10. The system, which has been described above, generated accordingly the principle explained in FIG. 1 is a hologram.

A method for reconstructing a hologram used in the above-described Manner is now generated with reference to FIG. 3 A to 3C.

As shown in Figure 3A, white light is projected from a light source 42 within the Y ^- -Z plane onto the holographic plate 2 from the side opposite the side from which an observer 43 is to view the reconstructed image. The light source is preferably a point source. The reconstructed image 41, which is observed in this way, is perceived stereoscopically, as follows with reference to FIG. 3A and 3C will be explained later.

The reconstruction of the image in the transverse direction (X- axis) is shown in FIG. 3B In the transverse direction, the reconstructed holographic image 416 is observed at a point at which the virtual (one-way) image 5, which is shown in FIG. 1, was formed with respect to the transverse direction of the object. However, since the hologram was formed in the transverse direction by the diverging wavefront of the virtual image 5, the reconstructed image which is generated by the white light has; a parallax. In this way, the reconstructed image 416 appears differently, depending on what the viewing angle is. It should be noted, however, that it is only observed as a one-way image.

If one now turns to FIG. 3C, one sees that the reconstructed image 41c is observed in the vertical direction (Y-axis) at the location of the holographic plate 2. With regard to the vertical direction, the hologram is an image hologram and does not change with the angle of observation (in the x, z-plane).

As in Fig. 3A is shown, is the reconstructed image according to the above-mentioned principle as a reconstructed image 41 observed resulting from the combination of the two reconstructed images 41b and 41c of Fig. 3B and Figure 3C. Any change in the angle of observation causes, as a result of the parallax of the reconstructed image 416, the combination of another image 416 with the reconstructed image 41c, whereby the observation becomes stereoscopic.

This is described in more detail below. Assume that the coordinates of the object point 1 are (xo, yo, 2b), the coordinates of the reference light source and the white light source used for the reconstruction are (xr, yn, Zr), and μ is equal to XcAr, where X _{c is} the If the wavelength of the light used in the reconstruction and λ «are the wavelength of the reference (recording) light, the coordinates of the reconstructed image (x _x , y _x , z \) result as follows:

Λ A =

If the coordinates of the reference light source (xr, ya zr) lie backwards and downwards within the Y- Z plane, and if

the position of the reconstructed image y _x Zz \ depends on the value of μ , i.e. on the ratio between the wavelengths of the light for the reconstruction and the reference light opposite side of the holographic plane as viewed from the observer), the position of the image varies with wavelength, combining the various images that are formed to form a single, blurred image. But is

2b = 0,

so that is, the image is on the holographic If the level is focused, the following relationship arises regardless of the value of μ:

z, = 0, 7i = 0,

so that the image reconstructed with white light emerges clearly on the holographic surface

On the other hand, substituting the values of (4) into equation (2) leads to the following relationship:

X _x Zz _x ■■
Because the value

is extremely small, the result is that the position defined by X ₁ Zz _x shifts only very little as a result of the changes in the value of μ, although the object point is a certain, finite distance in front of the holographic plane, the shift is in the The position of the reconstructed image resulting from the change in the wavelength is small in this case, so that the image obtained is relatively shallow

As can be clearly seen from the explanations above, the image assigned to the K-axis is present of the holographic surface, while the image assigned to the X-axis is a finite distance in front of the holographic surface. If this hologram is reconstructed with white light, which the

Has a tendency to increase the value of | y / zj, the image is nevertheless sharp in both the X and K directions. Furthermore, the parallax of the image in the A "direction causes a difference in the observation angle in the X-Z plane, which enables stereoscopic observation.

Needless to say that the reconstructed image can then be observed with utmost clarity when the reconstructed images have the same 41 b and 41c in the X- and K-direction magnification. To exclude a difference in magnification between the vertical and transverse direction and so as to ensure that b for the two reconstructed images 41 and 41c, the same observation angle is considered, it suffices to satisfy the following condition:

this can be accomplished in that the

\ r ^ nj: _ "._: i: _ ι: ._ _: _ j__ j"

Tk-IgIVUtIUlIg UUI JWfTWIIIgUtI l_illl3WII III UWIII XAUO

The hologram recording system is suitably selected in terms of the vertical and transverse directions will.

In an example of a practical application of the holograms that are generated according to the invention, the holographic plate 2 is moved laterally past a fixed observation point. One turns this method, it is when a number of separately prepared holographic plate elements 2a, 26 ... 2n are arranged so that one circular arc-shaped, composite holographic plate 2 results in the observation of a solid Point is rotated from, possible over angles that extend up to a full 360 °, a holographic image to be viewed stereoscopically.

The invention thus makes it possible to obtain a hologram of any desired size, even if the object in question is larger than the holographic plate used. This is at conventional holography processes are not possible.

In the embodiment of the invention described above, to focus the image Cylindrical lenses are used in both vertical and transverse directions. But it is also possible, any To use a combination of optical elements or optical systems, as long as only one combination leads to bundling light in one direction (in the direction of the X-axis), while another combination does that Light in the other direction (towards the Y- axis) bundles. Furthermore, it is also possible to use an optical element or optical elements or an optical system or systems on their major and minor axes differed-Ij ^ ji "Hrschkrsft ^e" '\ v ^e iss? I. In «£ S £ n Ρ * «» π soüte dss

μ hologram is best recorded after the vertical and lateral enlargements of an original (e.g. a transparent original) that should be recorded holographically, have been set so that the condition is met:

It / a = I / a + b.

It should be noted, however, that it is not absolutely necessary2 to set the magnifications in such a way that is applicable:

b <a.

and that an image of considerable clarity can be obtained even without such adjustment.

For this 2 blue drawings

Claims (1)

27 Ol 789 Claim; Device for recording a hologram of an object and for reconstructing the same with white light, with at least one source of coherent light and imaging optics between the object and the hologram in the recording arrangement, characterized in that in the recording arrangement between the object (1, 10) and the hologram ( 2) two AbbQdungsopttken (36, 3a) each with different refractive powers are provided in two mutually perpendicular main planes containing the optical axis, which are designed so that the object (1,10) in the first main plane on the hologram plane (2) and in the second half plane on one of the hologram plane, but at a short distance from this plane (5) compared to the object distance , and that in the reconstruction arrangement the light source (42) lies in the first main plane