JPH03174572A - Production of rainbow hologram - Google Patents

Abstract

PURPOSE:To produce the hologram having a high degree of freedom of use by irradiating the original plate of a master hologram with the divergent light made by an objective lens through a slit and a diffusion plate in contact with the slit as well as a subject in this order and irradiating the master plate with the collimated beams of light formed by a collimating lens as reference light, thereby generating interference fringes and executing recording. CONSTITUTION:One of the split laser beams bisected by a beam splitter 2 is collimated by a meter lens 7 and the master plate 11 of the master hologram is irradiated with the collimated beams 8 of light as the reference light. The other laser beam is reflected by a mirror 3b and is made incident to the objective lens 4b. The beam is made into the divergent light by the objective lens 4b and is made incident to the slit 5 mounted on the diffusion plate 6. The slit 5 selects a specific wavelength. The incident divergent light to the slit 5 is diffused by the diffusion plate 6 and is projected to the subject 10. The original plate 11 of the master hologram is irradiated with the light transmitted through the subject. The hologram for reconstruction of a wide area is obtd. by the small-sized objective lens 4c from the master hologram produced by this method. The hologram for reconstruction having the wide area is obtd. with the optical system of the low cost in this way.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Field of Application) The present invention relates to a rainbow hologram, and in particular, to near-divergent light reproduction that reproduces an image that pops out using diverging light from a light source placed close to a reproduction hologram. This invention relates to a method for producing a master hologram and a reproduction hologram.

(Prior Art) A method for manufacturing a master hologram and a reproduction hologram for a close-divergent reproduction hologram invented by Dr. Bent, ON is disclosed in, for example, U.S. Patent No. 3,633,
No. 989.

In the production of this type of hologram, when creating a reproduction hologram, a convergent light is required for the reference light, and in order to generate this, a fairly large lens or an aspherical concave mirror is required.

Figure 6 shows a conventional optical system for producing a master hologram.
Figure 7 shows a conventional optical system for producing holograms for reproduction.
Referring to FIG. 6, in manufacturing a master hologram, a laser beam emitted from a laser 1 is split into two by a beam splitter 2. One of the laser beams split by the beam splitter 2 is reflected by a mirror 3a and enters an objective lens 4a. The laser light is diverged by the objective lens 4a and further enters the collimator lens 7, where it becomes parallel light 8 and reaches the master hologram original plate.

This is the reference light.

The other laser beam split by beam splitter 2 is
The light is reflected by the mirror 3b, enters the objective lens 4b, and becomes diverging light by the objective lens 4c.

This diverging light is diffused by the diffusion plate 6, illuminates the subject 10, and reaches the master hologram original plate 11. This is object light 9.

The parallel light 8 emitted through the collimator lens 7 and the object light 9 generated by illuminating the subject 10 interfere, and the master hologram original plate 11 is exposed to interference fringes. The master hologram 11 is obtained by developing the exposed original plate 11 and subjecting it to a fixing process if necessary.

The production of a reproduction hologram will be explained with reference to FIG. 7. First, a slit 5 is attached to the master hologram 11. The slit 5 selects a specific wavelength, and in the conventional example, selects the wavelength of a white light source. A master hologram 11 with a slit 5 is subjected to conjugate reproduction, and an image 15 of a subject 10 is reproduced as a real image using parallel light 8 generated through a collimator lens 7. Using the obtained reproduced image 15 as object light and the convergent light 17 created by the large convex lens 14 or large concave mirror as reference light, the interference fringes are exposed onto the reproduction hologram original plate 12, and the original plate 12 is developed, as necessary. Perform fixing process. As a result, the reproduced image 15 and the slit 5 are recorded on the reproduction hologram 12.

FIG. 8 shows a conventional reproduction optical system for reproducing a recorded image from the reproduction hologram 12. The reproduction light source 16 is a white point light source (spotlight), and the position from the reproduction hologram 12 is as shown in FIG. The position of the reproduction light source point 18 shown in FIG. The position of this reproduction light source point 18 is determined by the large convex lens 14
(Figure 7). In the reproduction optical system shown in FIG. 8, a reproduction hologram 12 and a reproduction image 15
The distance between the reproduction hologram 12 and the reproduction image 15 in FIG. 7 is the distance between the reproduction hologram 12 and the reproduction image 15 in FIG. The object image 15 is viewed with the object image 15 placed immediately after the slit image 5'.

[Problem to be solved by the invention]

Conventionally, as described above, in the production of the reproduction hologram 12, convergent light is irradiated onto the reproduction hologram original plate using the convex lens 14 or a concave mirror, and the point light source 16 is placed at the focal point 18 of the convergent light in the reproduction optical system. It is necessary to illuminate the reproduction hologram 12. Playback hologram 12
If the distance between
In this case, the distance between the reproduction hologram 12 and the point light source 16 is long, and the reproduction hologram 12 must be illuminated from a distant position. Since the hologram reproduction device cannot be installed in a space, the manner in which the hologram reproduction device can be used is limited. From this point of view, it is preferable to shorten the distance between 12 and 16, but in order to do so, it is necessary to reduce the area of the reproduction hologram 12 or increase the diameter of the convex lens 14 or concave mirror. These problems include equipment limitations on the use of hologram reproduction devices, the impossibility of producing holograms that reproduce relatively large images, and the need to use expensive large-diameter lenses or concave mirrors. .

An object of the present invention is to manufacture a hologram with a high degree of freedom of use using an optical system that can be constructed at a relatively low cost.

[Structure of the invention]

(Means for Solving the Problems) In the present invention, first, a master hologram original plate (11
) is irradiated with diverging light produced by an objective lens (4b) through an optical system in which a slit (5), a diffuser plate (6) in contact with the slit (5), and a subject (10) are arranged in this order, The collimated light produced by the collimator lens (7) is irradiated as a reference light to generate interference fringes, which are recorded to obtain a master hologram.

When producing a reproduction hologram, the reproduction hologram original plate (12) is irradiated with a reproduction real image obtained by conjugate reproduction of the master hologram (11) produced as described above as object light, and the reproduction hologram original plate (12) is (12
) is irradiated with a diverging light produced by an objective lens (4c) close to the object lens (4c) as a reference light to generate interference fringes, which are recorded and a reproduction hologram is obtained. Note that symbols in parentheses indicate corresponding elements used in the embodiments described below with reference to FIGS. 1 and 2.

(Function) According to the master hologram manufactured in this way, as described above, the reproduction hologram original plate (12) is used.

A reproduced real image obtained by conjugate reproduction of the master hologram (11) is irradiated as an object light, and a diverging light produced by an objective lens (4c) close to the reproduction hologram original plate (12) is irradiated as a reference light. A reproduction hologram is obtained by generating and recording interference fringes. Since the reference light is a diverging light produced by the objective lens (4C), the objective lens (4C) and the hologram original plate for reproduction (1
2), it is possible to irradiate a relatively wide area with a relatively small diameter objective lens (4c). That is, according to the master hologram manufactured according to the present invention, a reproduction hologram with a relatively wide area can be obtained with a small-diameter objective lens (4c), and this type of objective lens (4c) can be used at an extremely low cost. Therefore, it is possible to obtain a wide-area reproduction hologram with a relatively low-cost optical system.

The reproduction hologram (12) manufactured as described above is
By placing a diverging light source (16) at the position where the objective lens (4c) was at the time of its manufacture and illuminating the reproduction hologram, the image (15) of the subject (10) becomes visible. By the way, since the objective lens (4C) is placed close to the reproduction hologram master plate (12), the distance between the two is extremely short, and therefore the reproduction hologram (
In the reproduction optical system of 12), the reproduction hologram (12)
The distance between the light source and the diverging light source (16) is extremely short. As a result, sufficient illumination is provided even if the emission intensity of the diverging light source (16) is low, and the degree of freedom in installing the reproduction optical system of the reproduction hologram is extremely high, allowing it to be installed in various relatively narrow spaces. It can also be used for purposes that are not allowed.

Other objects and features of the invention will become apparent from the following description of an embodiment with reference to one drawing.

(Example) Fig. 1 shows an exposure optical system when producing a master hologram according to the present invention, and Fig. 2 shows an exposure optical system when producing a reproduction hologram from the master hologram produced according to the present invention. 3 shows the figure of the object, FIG. 4 shows the object image reproducing optical system of the reproducing hologram manufactured according to the present invention, and FIG. 5a shows the reproducing hologram manufactured according to the present invention. 1 shows one usage mode of the hologram.

Figure 5b is a cross-sectional view of Figure 5a. Note that in these drawings, the same or corresponding parts as in the conventional example shown in FIGS. 6, 7, and 8 are shown.

The same code was given.

First, with reference to FIG. 1, the production of a master hologram according to the present invention will be explained. Laser light emitted from a laser 1 is split into two by a beam splitter 2, and one of the split laser lights is reflected by a mirror 3a. The beam is incident on the objective lens 4a, is diverged by the objective lens 4a, and is incident on the collimator lens 7, where the collimator lens 7 irradiates the master hologram original plate 11 as a reference beam of the parallel beam 8.

The other laser beam split by the beam splitter 2 is reflected by a mirror 3b, enters an objective lens 4b, becomes diverging light by the objective lens 4b, and enters this diverging light into a slit 5 attached to a diffuser plate 6. . The slit 5 is for selecting a specific wavelength, and in the present invention, it is matched to the wavelength of the white light reproduction light source 16 used when reproducing the reproduction hologram shown in FIG. The diverging light incident on the slit 5 is diffused by a diffuser plate 6 such as polished glass, illuminates the object IO, and the light transmitted through the object 10 (object light 9
) is irradiated onto the master hologram original plate 11.

FIG. 3 shows an image 15 formed on a translucent subject 10.
1 to 154 are shown. The object 10 is a HP transparent film on which images 151 to 154 are printed. In this example, images 151 to 154 are usage marks on key tops of lighting switches, heater switches, etc. on the vehicle. It is.

Referring again to FIG. 1, the parallel light 8 emitted through the collimator lens 7 interferes with the object light 9 produced by illuminating the subject 10, and the master hologram original plate 11 is exposed to the interference fringes. At this time, a reproduced image 15 of the subject 10 and a reproduced image 5T of the slit 5 are recorded on the master hologram original plate 11. The distance between the subject 10 and the slit 5 is 50 cs in this embodiment, and this is because the distance between the position of the eye (22; FIGS. 4 and 5b) and the reproduced image 15 during reproduction is 50 cm. It is.

The master hologram original plate 11 exposed as described above is developed and, if necessary, subjected to a fixing process to complete the production of the master hologram.

Next, the production of a reproduction hologram will be explained with reference to FIG. 2. As shown in FIG. 2, parallel light 8 is irradiated, and a real image 15 of the subject 10 is obtained by conjugate reproduction.
Play. At this time, the image 5' of the slit 5 is also reproduced. A hologram original plate 12 for reproduction is placed in advance between the reproduced image 15 and the master hologram 11, and the objective lenses 4a and 4b
The laser beam emitted from the laser 1 is diverged using an objective lens 4C similar to the one shown in FIG.
2. This diverging light 13 interferes with the object light that produces the reproduced image 15 of the subject 10 and the reproduced image 51 of the slit 5, and interference fringes appear, which expose the reproduction hologram 12. After completing this exposure, the reproduction hologram original plate 12 is developed and, if necessary, subjected to a fixing process to obtain a reproduction hologram. The distance between the center of the objective lens 4C and the center of the reproduction hologram original plate 12 is 10 to 30 cm in this embodiment due to the use described later.

As shown in FIG. 4, the obtained reproduction hologram 12 is illuminated with a diverging light source 16 placed at a position corresponding to the objective lens 4c in FIG.
The image 15 can be visually recognized with the eye 22 through the slit of the slit image 5'.

Fig. 5a shows one mode of use of the reproducing hologram 12 in which the reproducing hologram 12 produced as described above and the image reproducing optical system are mounted on a vehicle, and Fig. 5b shows a cross section of Fig. 5a. Show the diagram. On the back side of the reproduction hologram 12,
An incandescent lamp 16 is placed at a distance of 10 to 30 cm from the hologram 12, and illuminates the back side of the reproduction hologram 12.

With this illumination, 50 mm from the surface of the reproduction hologram 12 is
From the eye 22 placed at a distance of about c + w, the slit image 5'
Application marks 151 to 154 on key tops such as illumination light switches and heater switches can be seen through the slits.

The viewer uses his or her fingertip 21 to select the purpose mark that he/she wishes to operate.')1
5i (i=1 to 4).

The emitters 18e and receivers 18r of the infrared detectors 171-174 are directed toward the positions where the images of the application marks 15t-154 appear, and the infrared detectors 171-174 each have their fingertips 21 aligned with the marks. 151-154
is in the position where it appears, a switch-on signal is generated and provided to the lamp and heater controller 19.

The controller 19 responds to the switch-on signal to turn on/off the corresponding lamp or heater.

Since the distance between the incandescent lamp 16 and the reproduction hologram 12 is short, the reproduction optical system shown in FIGS. 5a and 5b can be constructed relatively compactly, and the incandescent lamp 16 has a small wattage but is bright. A mark image appears.

〔Effect of the invention〕

As described above, according to the present invention, in the production of a master hologram, the slit is attached to the diffuser plate in advance, so that the subject can be recorded on the master hologram with object light whose wavelength is selected by the slit. Therefore, when creating a reproduction hologram that can be reproduced with white light (divergent light), the reproduced image of the subject obtained by conjugate reproduction of the master hologram is used as the object light, and the object light and laser light are used as the object light. A reproduced image can be recorded on the reproduction hologram by interfering with the diverging light obtained through the hologram. Therefore, the reproduction image of this reproduction hologram can be reproduced by irradiating it with white light (divergent light).

Furthermore, according to the master hologram manufactured according to the present invention, it is possible to obtain a reproduction hologram with a relatively wide area with a small diameter objective lens (4c), and this type of objective lens (4c) can be used at an extremely low cost. Therefore, it is possible to obtain a wide-area reproduction hologram with a relatively low-cost optical system.

According to the reproduction hologram (12) manufactured according to the present invention, in the reproduction optical system, the reproduction hologram (12)
The distance between the light source and the diverging light source (16) is extremely short. As a result, sufficient illumination is provided even if the emission intensity of the diverging light g (16) is low, and the degree of freedom in installing the reproduction optical system of the reproduction hologram is extremely high, allowing it to be used in various relatively narrow spaces. It will now be possible to use it for purposes that are otherwise prohibited.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view showing an exposure optical system when producing a master hologram according to the present invention. FIG. 2 is a cross-sectional view showing an exposure optical system when producing a reproduction hologram according to the present invention. 3rd rpJ is a plan view showing a switch use mark printed on the subject 10 shown in FIG. 1. FIG. 4 is a cross-sectional view showing a reproduction optical system for a reproduction hologram produced using the exposure optical system shown in FIG. 2. FIG. 5a is a perspective view showing one mode of use of the reproduction hologram produced next to the exposure optical source shown in FIG.
Figure 5b is a cross-sectional view of Figure 5a. FIG. 6 is a cross-sectional view showing an exposure optical system used in the production of a conventional master hologram. FIG. 7 is a cross-sectional view showing an exposure optical system used in the production of a conventional reproduction hologram. FIG. 8 is a cross-sectional view showing a reproduction optical system for a reproduction hologram created using the exposure optical system shown in FIG. 7. 1: Laser beam W2: Beam splitter 3a, 3b, 3c: Mirror 4a, 4b: Objective lens 4c: Objective lens (objective lens) 5 Nislit (slit) 6: Diffusion plate (diffusion plate) 7: Collimator lens (collimator lens) 8: Parallel light (reference light) 9: Object light 10: Subject (subject) 11: Master hologram original plate 12: Hologram original plate for reproduction 13: Divergent light (J1! Divergent light) 14: Large diameter convex lens 15: Reproduced image of the subject 151 ~154
: Switch purpose mark 16: White light source 171-174: Infrared detector 186: Infrared emitter 18r: Receiver 19: Controller 21: Fingertip 22: Eye

Claims (2)

[Claims] (1) The master hologram original plate is irradiated with diverging light created by an objective lens through an optical system that includes a slit, a diffuser plate in contact with the slit, and a subject arranged in this order, and parallel light created by a collimator lens is referenced. irradiate it as light to generate interference fringes and record them.
A method for producing a rainbow hologram that reproduces a pop-up image using a white diverging light source. (2) A reproduced real image obtained by conjugate reproduction of the master hologram created by the manufacturing method of the above-mentioned patent item (1) is irradiated onto the reproduction hologram original plate as object light, and an objective light source close to the reproduction hologram original plate is irradiated. A method of manufacturing a rainbow hologram in which the diverging light created by a lens is irradiated as a reference light to generate and record interference fringes, and the pop-up image is reproduced using a white diverging light source.