JP5672431B2 - Reflection hologram manufacturing method and reflection hologram manufactured thereby - Google Patents

Description

  The present invention relates to a reflection hologram manufacturing method and a reflection hologram manufactured thereby.

  Since a hologram can reproduce a complete three-dimensional image, it is known that design diversity and excellent design can be imparted to a single hologram. Furthermore, in addition to a three-dimensional image, a two-dimensional two-dimensional pattern of multiple colors can be recorded in multiple layers or superimposed to create a hologram so that the reproduction positions of the reproduction patterns are different from each other, thereby providing a better design. This can be realized in Patent Document 1.

JP 2000-162952 A JP 2005-103991 A

  However, the hologram described in Patent Document 1 reproduces a hologram image with illumination light from one direction, and the illumination angle and the observation angle change when the hologram is observed from another direction. The hologram image could not be easily observed.

  The present invention has been made in view of such problems of the prior art, and its purpose is to produce a reflection hologram that can easily produce a reflection hologram that allows observation of a hologram image from various angles. It is to provide a method and a reflection hologram produced thereby.

A reflection hologram manufacturing method of the present invention that achieves the above-mentioned object is as follows.
In a method for producing a reflection hologram in which reproduction illumination light is incident and a hologram image is reproduced in a predetermined direction,
A first reflective hologram master that reproduces a hologram image in the predetermined direction by the first reproduction illumination light at the first incident angle, and a hologram image in the predetermined direction by the second reproduction illumination light at the second incident angle. The second reflective hologram master to be reproduced and the photosensitive material for hologram recording are arranged side by side so that the photosensitive material for hologram recording is on the predetermined direction side,
A reflective hologram is produced by making one beam of recording light enter the hologram recording photosensitive material from the predetermined direction ,
The predetermined direction is a direction perpendicular to the hologram recording photosensitive material,
At least one of the first reflective hologram master and the second reflective hologram master is disposed by being rotated by a predetermined angle in a plane parallel to the hologram surface of the hologram recording photosensitive material. It is characterized by that.

  Further, at least one of the first reflective hologram master and the second reflective hologram master is formed of a hologram scattering plate that scatters incident light that satisfies the Bragg condition.

  Further, at least one of the first reflective hologram master and the second reflective hologram master is composed of a hologram mirror that diffracts incident light that satisfies the Bragg condition.

  In addition, at least one of the first reflective hologram master and the second reflective hologram master has a relief pattern in which interference fringes generated by causing laser light to interfere are formed with fine irregularities. To do.

  Further, the first reflective hologram master is produced with light having a first wavelength, and the second reflective hologram master is produced with a second wavelength different from the first wavelength. .

  According to the reflection type hologram manufacturing method of the present invention, in the reflection type hologram manufacturing method in which the reproduction illumination light is incident to reproduce the hologram image in a predetermined direction, the first reproduction illumination light having the first incident angle is used to generate the reflection hologram. A first reflective hologram master for reproducing a hologram image in a predetermined direction, a second reflective hologram master for reproducing a hologram image in the predetermined direction by a second reproduction illumination light having a second incident angle, and hologram recording A photosensitive material is arranged side by side so that the photosensitive material for hologram recording is on the predetermined direction side, and recording light of one light beam is incident on the photosensitive material for hologram recording from the predetermined direction, whereby a reflection hologram is formed. Since it is manufactured, it is possible to easily manufacture a reflection hologram capable of observing the hologram image from various angles with one light beam.

  In addition, since the predetermined direction is a direction perpendicular to the hologram recording photosensitive material, the setting of the angle and the like can be simplified and it can be more easily manufactured.

  In addition, since at least one of the first reflective hologram master and the second reflective hologram master is disposed at a predetermined angle in a plane parallel to the hologram surface of the hologram recording photosensitive material, It is possible to realize design diversity and design with simple settings.

  In addition, since at least one of the first reflective hologram master and the second reflective hologram master is composed of a hologram scattering plate that scatters incident light that satisfies the Bragg condition, the design is further rich in design diversity. It is possible to produce a reflection hologram having excellent properties.

  In addition, since at least one of the first reflective hologram master and the second reflective hologram master is composed of a hologram mirror that diffracts incident light that satisfies the Bragg condition, the design is more versatile. It is possible to produce a reflection hologram excellent in the above.

  In addition, at least one of the first reflection hologram master and the second reflection hologram master has a relief pattern in which interference fringes generated by causing laser light to interfere are formed with fine irregularities. It is possible to produce a reflection hologram that is rich in variety and excellent in design.

  In addition, since the first reflective hologram master is made with light having a first wavelength and the second reflective hologram master is made with a second wavelength different from the first wavelength, colorization, etc. In addition, it is possible to produce a reflection hologram having a variety of designs and excellent design.

It is a figure which shows the process for producing a 1st hologram. It is a figure which shows the state which reproduced | regenerated the 1st hologram. It is a figure which shows the process for producing the 2nd hologram. It is a figure which shows the state which reproduced | regenerated the 2nd hologram. It is a figure which shows the process for producing the 3rd hologram of 1st Embodiment. It is a figure which shows the state which reproduced | regenerated the 3rd hologram of 1st Embodiment. It is a figure which shows the process for producing the 3rd hologram of 2nd Embodiment. It is a figure which shows the state which reproduced | regenerated the 3rd hologram of 2nd Embodiment.

  Hereinafter, a reflection hologram manufacturing method according to the present invention and a reflection hologram manufactured thereby will be described with reference to the drawings.

  First, a method for producing a hologram original plate which is a first stage hologram will be described. 1 is a diagram showing a process for producing a first hologram, FIG. 2 is a diagram showing a state in which the first hologram is reproduced, FIG. 3 is a diagram showing a process for producing a second hologram, and FIG. It is a figure which shows the state which reproduced | regenerated 2 holograms.

  In the present embodiment, as shown in FIG. 1, first, the first hologram recording photosensitive material 1 is arranged at a predetermined distance from the first object OB1. The first hologram recording photosensitive material 1 includes first object light 11 that is reflected or transmitted and scattered light from the first object OB1 and first reference light that is parallel light or substantially parallel light having the same wavelength as the first object light 11. The light 12 is incident from the side opposite to the first object OB1. The first object beam 11 and the first reference beam 12 interfere in the first hologram recording photosensitive material 1. When the first object beam 11 and the first reference beam 12 interfere with each other, interference fringes are generated in the first hologram recording photosensitive material 1. Thereafter, the first hologram recording photosensitive material 1 is post-processed to produce a first hologram 1 'as a hologram master.

  Next, the reproduction of the first hologram 1 'will be described. As shown in FIG. 2, in order to reproduce the first hologram 1 ′, the first reproduction illumination light 21 traveling in the opposite direction at the same wavelength as the first reference light 12 at the time of recording is applied to the first hologram 1 ′. Irradiate. The first reproduction illumination light 21 is diffracted in the first hologram 1 ′ and emits the first reproduction light 22. Then, the first reproduced image IM1 is formed at the position of the first object OB1 at the time of recording.

  Next, as shown in FIG. 3, the second hologram recording photosensitive material 2 is arranged at a predetermined distance from the second object OB2. Then, the second hologram recording photosensitive material 2 includes a second object light 31 which is reflected or transmitted and scattered light from the second object OB2 and a second reference consisting of parallel light or substantially parallel light having the same wavelength as the second object light 31. The light 32 is incident from the side opposite to the second object OB2. The second object light 31 and the second reference light 32 interfere in the second hologram recording photosensitive material 2. When the second object light 31 and the second reference light 32 interfere with each other, interference fringes are generated in the second hologram recording photosensitive material 2. Thereafter, the second hologram recording photosensitive material 2 is post-processed to produce a second hologram 2 'as a hologram master.

  Next, the reproduction of the second hologram 2 'will be described. As shown in FIG. 4, in order to reproduce the second hologram 2 ′, the second reproduction illumination light 41 traveling in the opposite direction at the same wavelength as the second reference light 32 at the time of recording is applied to the second hologram 2 ′. Irradiate. The second reproduction illumination light 41 is diffracted in the second hologram 2 ′ and emits the second reproduction light 42. Then, the second reproduced image IM2 is formed at the position of the second object OB2 at the time of recording.

  FIG. 5 is a diagram for explaining a method of producing the second hologram 3 ′ in the second stage of the first embodiment.

  First, the third hologram recording photosensitive material 3, the second hologram 2 ', the first hologram 1', and the back layer 8 are arranged side by side. The order of the first hologram 1 'and the second hologram 2' may be reversed. In addition, it is preferable to stack and arrange as in this embodiment.

  Then, the third reference light 51 enters from the third hologram recording photosensitive material 3 side. The third reference light 51 passes through the third hologram recording photosensitive material 3 and is diffracted by the first hologram 1 ′ as the third reproduction illumination light 51 ′ to emit the third reproduction light 61. Similarly, the third reference light 51 passes through the third hologram recording photosensitive material 3 and is diffracted by the second hologram 2 ′ as the fourth reproduction illumination light 51 ″ to emit the fourth reproduction light 62.

  The third reproduction light 61 is incident on the third hologram recording photosensitive material 3 as the third object light 61 ′, and the fourth reproduction light 62 is incident on the third hologram recording photosensitive material 3 as the fourth object light 62 ′. Interference fringes are generated in the third hologram recording photosensitive material 3. Thereafter, the third hologram recording photosensitive material 3 is post-processed to produce a third hologram 3 'as a hologram master.

  FIG. 6 is a diagram showing a third reproduction image and a fourth reproduction image by the third hologram of the first embodiment. In order to reproduce the third hologram 3 ', the third hologram 3' proceeds in the opposite direction at the same wavelength as the third object light 61 'and the fourth object light 62' during recording shown in FIG. The fifth reproduction illumination light 71 and the sixth reproduction illumination light 72 are irradiated. The fifth reproduction illumination light 71 and the sixth reproduction illumination light 72 are diffracted in the third hologram 3 ′ and emit a fifth reproduction light 81 and a sixth reproduction light 82. Then, the first reproduction image IM1 and the second reproduction image IM2 are formed at the positions of the first object OB1 and the second object OB2 at the time of recording the first hologram 1 'and the second hologram 2'.

  In this way, it becomes possible to produce a reflection hologram that allows holographic images to be observed from different directions by one-beam exposure of the third reference light, and can easily realize excellent design diversity and design. It becomes possible.

  FIG. 7 is a view for explaining a method of producing the second hologram 3 ′ in the second stage of the second embodiment. In the second embodiment, when the third hologram 3 ′ is manufactured, the second hologram 2 ′ is turned upside down from the first embodiment, that is, rotated 180 ° in a plane parallel to the hologram surface of the third hologram recording photosensitive material 3. Are arranged.

  First, the third hologram recording photosensitive material 3, the second hologram 2 ', the first hologram 1', and the back layer 8 are arranged side by side. At this time, the second hologram 2 'is arranged upside down. The order of the first hologram 1 'and the second hologram 2' may be reversed. In addition, it is preferable to stack and arrange as in this embodiment.

  Then, the third reference light 51 enters from the third hologram recording photosensitive material 3 side. The third reference light 51 passes through the third hologram recording photosensitive material 3 and is diffracted by the first hologram 1 ′ as the third reproduction illumination light 51 ′ to emit the third reproduction light 61. Similarly, the third reference beam 51 passes through the third hologram recording photosensitive material 3 and is diffracted by the second hologram 2 ′ as the fourth reproduction illumination beam 51 ″. The fourth reproduction light 62 is emitted.

  The third reproduction light 61 is incident on the third hologram recording photosensitive material 3 as the third object light 61 ′, and the fourth reproduction light 62 is incident on the third hologram recording photosensitive material 3 as the fourth object light 62 ′. Interference fringes are generated in the third hologram recording photosensitive material 3. Thereafter, the third hologram recording photosensitive material 3 is post-processed to produce a third hologram 3 'as a hologram master.

  FIG. 6 is a diagram showing a third reproduction image and a fourth reproduction image by the third hologram of the first embodiment. In order to reproduce the third hologram 3 ', the third hologram 3' proceeds in the opposite direction at the same wavelength as the third object light 61 'and the fourth object light 62' during recording shown in FIG. The fifth reproduction illumination light 71 and the sixth reproduction illumination light 72 are irradiated. The fifth reproduction illumination light 71 and the sixth reproduction illumination light 72 are diffracted in the third hologram 3 ′ and emit a fifth reproduction light 81 and a sixth reproduction light 82. Then, the first reproduction image IM1 and the second reproduction image IM2 are formed at the positions of the first object OB1 and the second object OB2 at the time of recording the first hologram 1 'and the second hologram 2'. However, the second reproduced image IM2 is reproduced upside down with respect to the first embodiment.

  In this way, it becomes possible to produce a reflection hologram that allows holographic images to be observed from different directions by one-beam exposure of the third reference light, and can easily realize excellent design diversity and design. It becomes possible.

  In carrying out the present embodiment, it is preferable to use an Ar laser having a wavelength of 488 nm and a DPSS laser having a wavelength of 532 nm as the laser light, and the photosensitive material for hologram recording described in Patent Document 1, but other materials may be used.

  As mentioned above, although the reflection type hologram manufacturing method of this invention and the reflection type hologram produced by it were demonstrated based on embodiment, this invention is not limited to these embodiment, A various deformation | transformation is possible.

  For example, in the present embodiment, two sets of object light and reference light are used. However, a hologram may be produced using more sets of object light and reference light. In the present embodiment, the angle of the third reference beam 51 is perpendicularly incident on the third hologram recording photosensitive material 3, but may be set to another angle. Furthermore, in the second embodiment, the second hologram 2 'is rotated 180 ° upside down. However, the second hologram 2' is not limited to this angle and may be rotated.

  Further, at least one of the first hologram 1 ′ and the second hologram 2 ′ may be a hologram scattering plate that scatters incident light that satisfies the Bragg condition described in Patent Document 1. Further, it is possible to produce a reflection hologram having a variety of designs and excellent design.

  Furthermore, at least one of the first hologram 1 'and the second hologram 2' may be a hologram mirror that diffracts incident light that satisfies the Bragg condition. Further, it is possible to produce a reflection hologram having a variety of designs and excellent design.

  In addition, at least one of the first hologram 1 ′ and the second hologram 2 ′ has a relief pattern in which interference fringes generated by interference of laser light as described in Patent Document 2 are formed with fine irregularities. But you can. Further, it is possible to produce a reflection hologram having a variety of designs and excellent design.

  Further, the first hologram 1 ′ may be produced by light having a first wavelength, and the second hologram 2 ′ may be produced by light having a second wavelength different from the first wavelength. It becomes possible to make a color, and it is possible to produce a reflection hologram having a variety of designs and excellent design.

DESCRIPTION OF SYMBOLS 1 ... Photosensitive material 1 'for 1st hologram recording ... 1st hologram (1st reflection type hologram original plate)
2 ... Photosensitive material for second hologram recording 2 '... Second hologram (second reflective hologram master)
3 ... Photosensitive material for third hologram recording (photosensitive material for hologram recording)
3 '... third hologram (reflection hologram)
8 ... back layer 11 ... first object light 12 ... first reference light 21 ... first reproduction illumination light 22 ... first reproduction light 31 ... second object light 32 ... second reference light 41 ... second reproduction illumination light 42 ... Second reproduction light 51 ... third reference light 51 '... third reproduction illumination light 51''... fourth reproduction illumination light 61 ... third reproduction light 61' ... third object light 62 ... fourth reproduction light 62 '... first 4 object light 71 ... fifth reproduction illumination light 72 ... sixth reproduction illumination light 81 ... fifth reproduction light 82 ... sixth reproduction light OB1 ... first object OB2 ... second object IM1 ... first reproduction image IM2 ... second reproduction image

Claims (5)

In a method for producing a reflection hologram in which reproduction illumination light is incident and a hologram image is reproduced in a predetermined direction,
A first reflective hologram master that reproduces a hologram image in the predetermined direction by the first reproduction illumination light at the first incident angle, and a hologram image in the predetermined direction by the second reproduction illumination light at the second incident angle. The second reflective hologram master to be reproduced and the photosensitive material for hologram recording are arranged side by side so that the photosensitive material for hologram recording is on the predetermined direction side,
A reflective hologram is produced by making one beam of recording light enter the hologram recording photosensitive material from the predetermined direction,
The predetermined direction is a direction perpendicular to the hologram recording photosensitive material,
At least one of the first reflective hologram master and the second reflective hologram master is arranged to be rotated by a predetermined angle in a plane parallel to the hologram surface of the hologram recording photosensitive material. Reflective hologram manufacturing method.   2. The reflection according to claim 1, wherein at least one of the first reflection hologram original plate and the second reflection hologram original plate is formed of a hologram scattering plate that scatters incident light that satisfies a Bragg condition. Mold hologram manufacturing method.   3. The at least one of the first reflective hologram master and the second reflective hologram master comprises a hologram mirror that diffracts incident light that satisfies the Bragg condition. 4. Reflective hologram manufacturing method.   At least one of the first reflective hologram master and the second reflective hologram master has a relief pattern in which interference fringes generated by causing laser light to interfere with each other have fine irregularities. The reflection hologram manufacturing method according to any one of claims 1 to 3.   The first reflective hologram master is produced with light having a first wavelength, and the second reflective hologram master is produced with a second wavelength different from the first wavelength. The reflection hologram production method according to any one of claims 1 to 4.

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