JP3435785B2 - Holographic stereogram manufacturing method and apparatus - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a holographic stereogram (hereinafter referred to as "HS") having a wide viewing range and an apparatus for the same.

[0002]

2. Description of the Related Art In order to produce such a wide viewing area HS, a parallax image of a subject 1 is first photographed as shown in FIG. The camera 2 is arranged with respect to the subject 1, and the camera 1 is moved in the arrow (a) direction so that a desired viewing area Φ can be obtained. At this time, a plurality of parallax images are obtained by photographing the subject 1 each time the camera 1 moves by a predetermined distance.

Next, in the first stage, as shown in FIG. 11, the diffusion screen 3 having a large screen is arranged, and the parallax image 4 is projected and imaged on the diffusion screen 3 through the projection lens 5.

On the other hand, a large-sized first photosensitive material (for example, 25 cm in length) 6 is arranged on the opposite side of the diffusion screen 3, and a slit plate 7 is arranged on the front side thereof. The observation distance between the diffusion screen 3 and the first photosensitive material 6 is set to 41 cm, for example.

Therefore, the parallax image 4 is projected onto the diffusion screen 3 in the order in which the subject 1 is photographed, and the reference light is irradiated onto the first photosensitive material through the slit plate 7. This causes interference between the diffused light from the diffusing screen 3 and the reference light, and the interference fringes are recorded on the first photosensitive material 6.

At this time, the first photosensitive material 6 records interference fringes as the first element hologram by aligning the right end portion with the slit position, for example, and each time the parallax image 4 is switched, it is sequentially indicated by the arrow (b) direction. Then, the position where the interference fringes as the next element hologram are recorded is changed to record the element hologram by all parallax images. As a result, the master HS is created.

Next, in the second stage, the master HS
And the second photosensitive material are arranged so as to face each other, and the real image reproducing illumination light is irradiated to the master HS, and at the same time, the reference light is irradiated to the second photosensitive material.

As a result, interference fringes of the reproduced image and the reference light are recorded on the second photosensitive material, and an HS having a wide viewing area is produced.

[0009]

However, such a method for producing a wide viewing area HS requires a large-sized diffusion screen 3 and a first photosensitive material 6 having a wide horizontal width.

The diffusing screen 3 and the first photosensitive material 6 are also provided.
The observation distance between and is preferably narrow, but if this observation distance is reduced, it becomes difficult to irradiate the reference light between the diffusion screen 3 and the first photosensitive material 6.

Further, a large size diffusing screen 3
Also, it is extremely difficult to obtain an optical lens when the photosensitive material 6 is used, and it is expensive.

It is therefore an object of the present invention to provide a holographic stereogram manufacturing method and apparatus capable of easily manufacturing a wide viewing area hologram.

[0013]

According to claim 1, there is provided a first
In the step, the parallax image projected on the diffusion screen is recorded on the first photosensitive material to create a master hologram,
In the method of producing a holographic stereogram in which a reproduced image of a master hologram is recorded on a second photosensitive material in a second step, the first step is to reflect diffused light from a diffusing screen by a mirror. The light is guided to the first photosensitive material and part of the diffused light is shielded to selectively guide it to the first photosensitive material. In the second step, the reproduced image of the master hologram is reflected by the mirror arranged at the same position as the mirror. In this way, the holographic stereogram is produced by trying to achieve the above object by guiding the second photographic material.

According to the second aspect, in the first step, when recording the parallax image of the viewing area of at least one end of the parallax image on the first photosensitive material, the diffused light from the diffusing screen is reflected by the mirror. When the parallax image in the central viewing area is recorded on the first photosensitive material while reflecting the reflected light to the first photosensitive material and blocking the diffused light reflected by the mirror, the parallax image projected directly on the diffusion screen is directly recorded. The parallax images in these visual areas are led to the first photosensitive material and are subjected to multiple exposure on the first photosensitive material.

According to the third aspect, in the first step, the parallax image projected on the diffusion screen is recorded on the first photosensitive material to create a master hologram, and in the second step, the reproduced image of the master hologram is changed to the second image. A holographic stereogram producing apparatus for producing a hologram by recording on a light-sensitive material of, a first mirror arranged on at least one side surface of a diffusion screen to guide the diffused light to the first light-sensitive material, and a diffused light Is arranged with respect to the master hologram in the same relationship as the arrangement relationship of the light shielding plate that selectively shields a part of the light and selectively guides it to the first photosensitive material, and the first hologram with respect to the first photosensitive material. And a second mirror for guiding the reproduced image of the above to a second light-sensitive material, and a device for producing a holographic stereogram for achieving the above object. It is.

According to the fourth aspect, when the parallax image is recorded on the first photosensitive material, the light shielding plate varies the position where the diffused light is blocked according to the viewing area of the parallax image.

According to the fifth aspect, when the parallax image is recorded on the first photosensitive material, the light shielding plate forms an aperture of scattered light according to the viewing area of the parallax image.

[0018]

According to the first aspect, in the first step, the parallax image is projected on the diffusing screen, the diffused light from the diffusing screen is reflected by the mirror and guided to the first photosensitive material, and a part of the diffused light is generated. Is shielded and selectively guided to the first photosensitive material to form a master hologram.

In the next second step, the reproduced image of the master hologram is reflected by a mirror arranged at the same position as the mirror and is guided to the second photosensitive material for recording to produce a holographic stereogram.

According to the second aspect, in the first step, when the parallax image at the end of the viewing zone is recorded on the first photosensitive material, the diffused light from the diffusing screen is reflected by the mirror and the first photosensitive material is reflected. The recording is performed by blocking the light other than the diffused light reflected by the mirror and reflected by the mirror. By thus reflecting the light with a mirror, it is possible to record a parallax image taken in a wide viewing area.

When recording a parallax image at the center of the viewing zone on the first photosensitive material, the scattered light from the diffusing screen is directly guided to the first photosensitive material, and is recorded on the edge of the viewing zone. Multiple exposures are recorded.

According to the third aspect, in the first step, the parallax image is projected on the diffusing screen, and the diffused light from the diffusing screen is reflected by the first mirror arranged on one side surface of the diffusing screen. To a first photosensitive material, and at the same time, a part of the diffused light is shielded by a light shielding plate and selectively guided to the first photosensitive material to form a master hologram.

In the next second step, the reproduced image of the master hologram is reflected by the second mirror arranged at the same position as the first mirror, guided to the second photosensitive material and recorded, and the holographic stereo is used. Make a gram.

According to the fourth aspect, the position of the light shielding plate for shielding the diffused light is variable according to the viewing area of the parallax image.

According to the fifth aspect, the light shielding plate allows the scattered light to pass from the aperture corresponding to the viewing area of the parallax image.

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

(1) First, a parallax image of the subject 1 is taken. In this parallax image, the camera 2 is arranged with respect to the subject 1 as shown in FIG.
Is moved in the direction of arrow (a) so that a desired viewing area Φ can be obtained. At this time, a plurality of parallax images are obtained by photographing the subject 1 each time the camera 1 moves by a predetermined distance.

In this case, a parallax image of the maximum observation range (maximum viewing zone) determined based on the observation distance from the diffusion screen to the first photosensitive material in the first stage and the horizontal width of the first photosensitive material is obtained. Take a picture.

(2) Next, the first stage of producing the wide viewing area HS will be described.

In the first step, the diffused light from the diffusing screen is reflected by the mirror and guided to the first photosensitive material, and a part of the diffused light is shielded to selectively guide it to the first photosensitive material. Create HS.

That is, FIGS. 1 and 2 are block diagrams of the master HS producing optical device applied to the first stage.
Is an external view and FIG. 2 is a plan view.

The parallax image (original image) 10 is wound for each image and projected onto the diffusion screen 12 through the projection lens 11.

A first photosensitive material 13 is arranged on the diffusion screen 12 at a predetermined observation distance.
The slit plate 14 is disposed on the front side of the photosensitive material of FIG.

Further, first mirrors 15 and 16 are arranged on both ends of the diffusing screen 12 in a direction perpendicular to the diffusing screen 12, respectively. These first mirrors 15 and 16 are arranged when recording the parallax images at both ends of the viewing zone, and are removed when recording the parallax image at the center of the viewing zone.

The left and right sides of the diffusion screen 12 and the first photosensitive material 13 are determined as shown in the drawing, and the mirror 1
5 is a right mirror 15 and mirror 16 is a right mirror 16.

Further, the light shielding plate 17 is the diffusion screen 12
And the first photosensitive material 13 are arranged. The shading plate 17 is movable in the direction of the arrow (c), and when recording parallax images at both ends of the viewing area, it shields a part of the diffused light from the diffusing screen 12 to selectively perform the first photosensitization. Material 13
That is, only the scattered light reflected by the right or left mirror 15, 16 out of the diffused light from the diffusing screen 12 is first
It is for leading to the photosensitive material 13.

Next, a method of creating the master HS in the first stage will be described.

(A) First, a case will be described in which a parallax image (observation region "3") photographed at the photographing position Q1 of the parallax image is recorded as shown in FIG.

Parallax image 1 photographed at this photographing position Q1
0 is arranged, the mirrors 15 and 16 are arranged on both ends of the diffusion screen 12, and the light shielding plate 17 is arranged in contact with the left mirror 16. Further, the first photosensitive material 13 is moved and arranged so that its right end hits the slit position.

In this state, the parallax image 10 is projected onto the projection lens 1.
1 is projected on the left end of the diffusion screen 12. As shown in FIG. 3, the projected parallax image is diffused by the diffusing screen 12, reflected by the right mirror 15, and irradiated onto the first photosensitive material through the slit.

At this time, of the diffused light, the diffused light not reflected by the right mirror 15 is blocked by the light shielding plate 17.

In this way, the scattered light is reflected by the right mirror 15 and is incident on the first photosensitive material 13, so that when viewed from the first photosensitive material 13, the scattered light is incident from the image position (virtual image) S1. It will be done.

Therefore, when the first light-sensitive material 13 is irradiated with the reference light, the scattered light by the parallax image and the reference light interfere with each other, and the interference fringes form the first light-sensitive material as the first element hologram. It is recorded at the right end of 13.

Next, the parallax image 10 is changed from the previous parallax image to the adjacent parallax image, and the first photosensitive material 13 is shifted rightward by one element hologram width.

Further, the light shielding plate 17 is shifted toward the right mirror 15. It should be noted that the light shield plate 17 and the left mirror 16 are shielded from light without a gap.

In this state, the parallax image 10 is projected onto the projection lens 1.
When projected on the left end of the diffusion screen 12 through 1,
The diffused light is reflected by the right mirror 15 and irradiates the first photosensitive material through the slit.

At this time, of the diffused light, the diffused light that is not reflected by the right mirror 15 is blocked by the light shielding plate 17 as described above.

In this way, the scattered light is reflected by the right mirror 15 and is incident on the first photosensitive material 13, so that when viewed from the first photosensitive material 13, the scattered light is incident from the image position (virtual image) S2. It will be done.

Therefore, when the first photosensitive material 13 is irradiated with the reference light, the scattered light due to the parallax image and the reference light interfere with each other, and the interference fringes form the second photosensitive element hologram of the first photosensitive material. It is recorded at the next position at the right end of 13.

Similarly, the parallax image 10 is sequentially changed to the adjacent parallax image, the first photosensitive material 13 is shifted rightward by one element hologram width, and the light shielding plate 17 is moved to the right mirror 15. The first element hologram is recorded by shifting to. As a result, recording on the observation area “3” is completed.

(B) Next, a case will be described in which a parallax image (observation region "2") photographed at the photographing position Q2 at the center of the parallax image is recorded as shown in FIG.

In this case, as shown in FIG. 4, the photographing position Q2
The parallax image 10 photographed in (3) is projected on the diffusion screen 12, and the mirrors 15 and 16 and the light shielding plate 17 are removed.

The first photosensitive material 13 is the one on which the previously recorded observation area "3" has been recorded, and is moved and arranged so that the right end thereof hits the slit position.

In this state, the diffused light from the diffusing screen 12 enters the first photosensitive material 13 through the slit, and the reference light enters the first photosensitive material 13.
As a result, the portion previously recorded as the first element hologram is multiply exposed.

Thereafter, similarly, the parallax image 10 is sequentially changed to the adjacent parallax image, and the first photosensitive material 13 is shifted rightward by one element hologram width,
Recording of each element hologram is performed. As a result, the recording for the observation area “2” ends.

(C) Next, a case will be described in which a parallax image (observation region "1") photographed at the photographing position Q3 of the parallax image is recorded as shown in FIG.

The parallax image 10 photographed at the photographing position Q3 is arranged, and as shown in FIG.
6 are arranged on both ends of the diffusion screen 12,
Moreover, the light shielding plate 17 is arranged in contact with the right mirror 16.
In addition, the first photosensitive material 13 is first in each observation area “3”.
Recording is performed for "2", and the left end of the recording is moved and arranged so as to hit the slit position.

In this state, the parallax image 10 is projected onto the projection lens 1.
1 to the right end of the diffusion screen 12. As shown in FIG. 5, the projected parallax image is diffused by the diffusing screen 12, reflected by the left mirror 15, and irradiated onto the first photosensitive material 13 through the slit.

At this time, of the diffused light, the diffused light not reflected by the left mirror 16 is blocked by the light blocking plate 17.

In this way, the scattered light is reflected by the left mirror 16 and is incident on the first photosensitive material 13, so that from the perspective of the first photosensitive material 13, the scattered light is incident from the image position (virtual image) Sn. It will be done.

Therefore, when the first light-sensitive material 13 is irradiated with the reference light, the scattered light due to the parallax image and the reference light interfere with each other, and the interference fringes are the first element hologram of the observation area “1”. Is recorded on the left end of the first photosensitive material 13.

Similarly, the parallax image 10 is sequentially changed to the adjacent parallax image, the first photosensitive material 13 is shifted leftward by one element hologram width, and the light shielding plate 17 is moved to the left mirror 16 in the same manner. The first element hologram is recorded by shifting to. As a result, the recording for the observation area “1” is completed.

As described above, recording of each parallax image of each observation area "3""2""1" on the first photosensitive material 13 is completed, and the first photosensitive material 13 is used as a master HS.

(2) Next, the second stage of wide-field HS production is started.

In the second stage, the reproduced image of the master HS is reflected by the mirrors arranged at the same positions as the mirrors 15 and 16 and is guided to the second photosensitive material, so that the wide viewing area HS is obtained.
To make.

That is, FIGS. 6 and 7 are configuration diagrams of the wide viewing zone HS producing optical device applied to the second stage, FIG. 1 is an external view and FIG. 2 is a plan view. A second photosensitive material (holographic photosensitive material) 21 is arranged to face the master HS 20 at a predetermined interval.

Further, the mirrors 22 and 23 are arranged on both ends of the master HS 20 and the second photosensitive material 21, respectively. These mirrors 22 and 23 are the right mirror 1 arranged on the first photosensitive material 13 in the first stage.
5 and the left mirror 16 are arranged in the same relationship as the master H
It is arranged with respect to S20.

When the master HS 20 is irradiated with the real image reproducing illumination light in this state, a diffracted reproduced image appears in the direction opposite to the recorded diffused light.

Of these, the diffraction reproduced images of the observation areas “3” and “1” are reflected by the mirrors 22 and 23 to form images on the second photosensitive material 20, and the diffraction reproduced images of the observation area “2” are An image is directly formed on the second photosensitive material 20.

At this time, when the reference light is incident on the second photosensitive material 21 from the direction opposite to the incident direction of the diffracted reproduction image, interference occurs between the diffracted reproduction image and the reference light, and the interference fringes are generated. It is recorded on the second photosensitive material 21, and as a result, a wide viewing area H
S is produced.

(3) Wide viewing area HS produced in this way
When you replay, each observation area “1” is displayed as shown in FIG.
It has a viewing zone Φ corresponding to “2” and “3”. The viewing area θ is the case of the conventional HS.

As described above, in the first embodiment,
In the first stage, the diffused light from the diffusing screen 12 is reflected by the respective mirrors 15 and 16 so that the first photosensitive material 1
Selective first by blocking part of the diffused light while guiding to
To the master's photosensitive material 13 to create a master hologram,
In the next second step, the reproduced image of the master HS is reflected by the respective mirrors 22 and 23 and guided to the second photosensitive material 21 to be recorded, so that the wide viewing area HS is produced. That is, it is possible to manufacture an HS having a viewing zone three times as large as that of the conventional one.

Further, in order to manufacture this wide viewing area HS, it is possible to easily and inexpensively use an off-the-shelf projection lens, a diffusing screen, and a light-sensitive material without using special parts for the optical system. it can.

In addition, the operation of the light shielding plate and the setting of the exposure sequence are simple, and hologram synthesis can be easily performed.

The present invention is not limited to the above-mentioned embodiment but may be modified as follows.

For example, in the first step, the light shielding plate may have a function of passing only the diffused light reflected by the mirror and shielding the other light.

Therefore, as shown in FIG. 9, when the diffused light from the diffusing screen 30 is reflected by a mirror (not shown) to irradiate the photosensitive material 31, the diffusing screen 30 is seen from the photosensitive material 31 by the reflection of the mirror. In order to show each virtual image position, an aperture 33 that allows light reflected from the mirror to pass through may be formed in the light shielding plate 32. The aperture 33 is not limited to a rectangle, but may be formed in a circle or the like.

In the above embodiment, the light shield plate is the first
Although the photosensitive material 13 is moved in the same direction as the moving direction, the movement may be moved in the vertical direction according to the recording method.

Further, in the above-mentioned one embodiment, the observation area of 3 times is obtained, but if the distance between the diffusion screen and the first photosensitive material is narrowed, the observation area of plural times can be obtained.

[0080]

As described above in detail, according to the present invention, it is possible to provide a method and an apparatus for producing a holographic stereogram capable of easily producing a hologram having a wide visual range.

[Brief description of drawings]

FIG. 1 is an external configuration diagram showing an embodiment of an apparatus for producing a holographic stereogram applied to the first stage according to the present invention.

FIG. 2 is a plan configuration diagram of the device.

FIG. 3 is a diagram showing a recording operation at the end of the viewing zone by the same device.

FIG. 4 is a diagram showing a recording operation in the center of the visual field by the same device.

FIG. 5 is a diagram showing a recording action at the end of the viewing zone by the same device.

FIG. 6 is an external configuration diagram showing an embodiment of a holographic stereogram producing apparatus applied to the second stage according to the present invention.

FIG. 7 is a plan configuration diagram of the device.

FIG. 8 is a diagram showing a viewing area of a reproduced image of a wide viewing area HS.

FIG. 9 is a configuration diagram showing another example of the light shielding plate.

FIG. 10 is a diagram showing a method of capturing a parallax image.

FIG. 11 is a view showing a conventional HS manufacturing method.

[Explanation of symbols]

1 ... Subject, 10 ... Parallax image, 11 ... Projection lens, 12
... Diffusion screen, 13 ... First photosensitive material, 14 ... Slit plate, 15, 16 ... First mirror (right mirror, left mirror), 17 ... Shading plate, 20 ... Master HS, 21 ... Second
Photosensitive material, 22, 23 ... Mirror.

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Claims (5)

(57) [Claims] 1. A master hologram is created by recording a parallax image projected on a diffusion screen in a first photosensitive material in a first step, and a reproduced image of the master hologram is recorded in a second photosensitive material in a second step. In the method for producing a holographic stereogram for recording and producing a hologram, in the first step, the diffused light from the diffusing screen is reflected by a mirror and guided to the first photosensitive material, and at the same time, one of the diffused light is produced. The second photosensitive material is selectively guided to the first photosensitive material by shielding a portion thereof, and in the second step, a reproduced image of the master hologram is reflected by a mirror arranged at the same position as the mirror. A method for producing a holographic stereogram, which is characterized by the above. 2. In the first step, when recording a parallax image of a viewing zone of at least one end of the parallax image on the first photosensitive material, the diffused light from the diffusing screen is reflected by a mirror and the When the parallax image in the central viewing area is recorded on the first photosensitive material while the light other than the diffused light reflected by the mirror is guided to the first photosensitive material, the parallax image projected on the diffusion screen is directly 2. The method for producing a holographic stereogram according to claim 1, wherein the parallax images in these viewing zones are exposed to the first light-sensitive material and multiple-exposure is performed on the first light-sensitive material. 3. A parallax image projected on a diffusing screen is recorded on a first photosensitive material in a first step to create a master hologram, and a reproduced image of the master hologram is recorded on a second photosensitive material in a second step. In a holographic stereogram producing apparatus for producing a hologram by recording, a first mirror which is disposed on at least one side surface of the diffusion screen to guide diffused light to the first photosensitive material, and the diffused light A light-shielding plate that partially shields the light-shielding plate and selectively guides the light-sensitive material to the first photosensitive material, and is arranged with respect to the master hologram in the same relationship as that of the first mirror with respect to the first photosensitive material.
A holographic stereogram producing apparatus comprising: a second mirror for guiding a reproduced image of the master hologram to the second photosensitive material. 4. The hollow according to claim 3, wherein when the parallax image is recorded on the first photosensitive material, the light blocking plate changes a position for blocking the diffused light in accordance with the viewing area of the parallax image. Graphic stereogram production equipment. 5. The holographic device according to claim 3, wherein the light-shielding plate forms an aperture of scattered light according to a viewing area of the parallax image when the parallax image is recorded on the first photosensitive material. Stereogram production equipment.