HOLOGRAM RECORDING MEDIUM AND METHOD FOR THE PRODUCTION THEREOF, HOLOGRAM REPRODUCTION DEVICE AND HO

专利摘要:

公开号:AT510099A2
申请号:T0090211
申请日:2011-06-21
公开日:2012-01-15
发明作者:
申请人:Sony Corp；Sony Dadc Corp；
IPC主号:

专利说明:

1
HOLOGRAM RECORDING MEDIUM AND METHOD FOR THE PRODUCTION THEREOF, HOLOGRAM PLAYING DEVICE AND HOLOGRAM PLAYER PROCESSING
AREA OF EXPERTISE
This invention relates to a hologram recording medium and a method of manufacturing the same, a hologram reproducing apparatus and a hologram reproducing method. More particularly, it relates to a hologram recording medium in which many pieces of information such as characters, bar codes and other image information expressed in a planar form are recorded, and a method of manufacturing the hologram recording medium. Further, the present disclosure relates to a hologram reproducing apparatus that reproduces information recorded on the hologram recording medium and converts the reproduced information in an optical-to-electrical conversion method, as well as a hologram recording apparatus.
Reproduction process,
BACKGROUND
A hologram that provides spatial representation is used to verify the authenticity of a credit card, ID card, or other ID card. Among many types of hologram, in recent years, a volume hologram in which an interference pattern in the form of differences in refractive index on a recording layer is often used is used. The reason for this is that it is difficult to duplicate a volume hologram without using a sophisticated technology for recording an image, and that a recording material used in a volume hologram is difficult to obtain.
On the other hand, a volume hologram copying technology is progressing day by day, and it is desired to have a hologram with a more sophisticated authentication function as well as tamper-proof
Characteristics is delivered. Further, there is a need for a simple confirmation of authenticity, for example by machine reading information recorded in a hologram.
An image change hologram that allows a reproduced image to be changed in accordance with the direction from which the hologram is viewed is disclosed as a method for providing a hologram having a more sophisticated authentication function (for example, see JP-A-A). 2008-122670).
However, in the above-described hologram image change, it is possible to visually recognize many pieces of recorded image information, which is inconvenient. Further, since a single original is used to make a large number of holograms, it is difficult to provide that the holograms themselves have a more sophisticated authentication function, for example, allowing the holograms to be individually recognized.
SUMMARY
It is desirable to provide a hologram recording medium that is tamper-proof and easy, and a method of manufacturing the hologram recording medium, a hologram reproducing apparatus, and a hologram reproducing method.
The inventors have made intensive research to solve the problems described above in connection with the prior art, having obtained a hologram recording medium on which an image reproduced from an original of the hologram and an image are reproduced Identification information (hereinafter referred to as individual ID information) is recorded in an individual hologram.
As mentioned above, there is a need to be able to machine-read information recorded in a hologram. For example, there has been a demand to reproduce character information, bar code information, and other information recorded in a hologram as individual ID information, to convert the reproduced optical information into electrical information by using an imaging camera or any other suitable means, and to read the electrical information by machine.
In order to reproduce information recorded in a hologram, it is necessary that the hologram be illuminated with light, for example with collimated light traveling in a single direction or with light from a point source of light. When the hologram is illuminated with light rays from a variety of different directions, a plurality of images are reproduced and adversely superimposed to form multiple images. This means that the reproduced hologram images disadvantageously produce a blurred image.
When the information reproduced from the hologram generates multiple images, it is difficult for the images to be accurately read out by machine.
To address this problem, the inventors have made intensive studies on a hologram recording medium which reproduces holographically recorded character information, bar code information, and other information without generating multiple images. Thus, the inventors have obtained a hologram recording medium which enables many pieces of information to be recorded, wherein any one of many pieces of image information is expressed in a planar form so as to reproduce them selectively within a certain angular range only when the hologram coincides Light is illuminated from a given direction.
A preferred embodiment of a hologram recording medium is constructed as will now be described.
Two or more images are recorded on the hologram recording medium; 4, when substantially collimated light falls on the hologram recording medium along a first direction, a first image is reproduced, wherein the intensity of light diffracted in the hologram recording medium is maximized in a predetermined direction; when substantially collimated light is incident on the hologram recording medium along a second direction, a second image is reproduced, wherein the intensity of light diffracted in the hologram recording medium is maximized in the predetermined direction; and the whole width of a reproduction angle at the half maximum of at least one of the intensities of the diffracted light of the first and second images is equal to or smaller than 8 °.
A preferred embodiment of a method for
Preparation of a hologram recording medium is constructed as will now be described.
The method comprises modulating laser beams in spatial light modulators into laser beams, each of which contains additional information, and illuminating a hologram recording medium by optical focusing systems with the modulated laser beams together with a reference light beam; and providing at least one diffusion angle by one of the focusing optical systems having an absolute value that is 7 ° or smaller.
A preferred embodiment of a hologram
Playback apparatus is constructed as will now be described.
The device comprises: a viewing table having an opening, a holding element which is at least part of the
A viewing table, a Lichtabsperrelement having a Lichtabsperrteil and is mounted on the holding member on a side which is closer to a viewer than the viewing table, and 5 a plurality of light sources, which are mounted on the holding member; while the viewing table is constructed so that a
Hologram can be placed, which is visible when it is in the opening; In doing so, each of the plurality of light sources illuminates the
Hologram in a given direction; In this case, a part of the Lichtabsperrelements, which corresponds to a part at least above the opening, an optical opening; and the light-blocking member prevents illuminating light from each of the light sources from leaking directly through the optical opening.
A preferred embodiment of a method for
Viewing a hologram is constructed as will now be described.
The method includes: {setting the direction of a normal to a hologram on which many pieces of image information are recorded, a direction of the illumination light illuminating the hologram, and a direction from which the hologram is viewed),
Selecting one of image information from the many pieces of image information recorded in the hologram by fixing any of two directions and changing the retial direction, and
Viewing the selected image information.
In accordance with the preferred embodiment of a hologram recording medium, the whole width of the diffracted light intensity at half maximum is set on an image reproduced from the hologram recording medium. That is, the information recorded on the hologram recording medium has been recorded with an object light having a predetermined diffusion angle. The information is thus recorded on the hologram recording medium in a plane form, and then, when the hologram recording medium is illuminated with light 6 from a predetermined direction, a sharp image is reproduced.
In accordance with the preferred embodiment of the hologram reproducing apparatus, a hologram can be arranged and aligned in the opening in the viewing table. Thus, the hologram can be reliably illuminated with light from a given direction, wherein the information recorded in the hologram can be reliably recognized by a viewer even if the whole width of the intensity of the diffracted light at half maximum on an image is determined by the Hologram is reproduced.
The intensity of the diffracted light here refers to a value measured using the following method. Figs. 26A and 26B are simplified diagrams showing a method of measuring the
Intensity of the diffracted light is shown. A hologram 101 to be measured is placed on a black plate 102, as shown in Fig. 26A. A measuring device 7 01 is arranged above the hologram 101 in the direction of a normal thereon at a distance of 380 mm thereof. A light source 202 is fixed at a position obliquely inclined to the hologram 101 at 45 ° to the direction of the normal.
When measuring the measuring devices and other components are used, which will now be described.
Measuring equipment: Luminance meter and colorimeter (Konica-Minolta CS-200)
Light source: halogen light source (Y: 96.0, X: 0.4508, Y: 0.4075 in an XY chromaticity diagram) standardized white plate: (Konica-Minolta CSA-20)
The illumination light source 202 illuminates the hologram 101, wherein the measuring device 7 01 measures the light (diffracted light) reproduced by the hologram 101. During the measurement, the field of view is set to 0.2 °, (x, y) the color coordinates and the luminance LU1. Then, the hologram is replaced by 7 the standardized white plate, which is a reference value, and the same measurement is performed on the standardized white plate to measure the (x, y) color coordinates and the light intensity LU2 Field of view is set to 0.2 °. The intensity I of the light diffracted in the hologram 101 should be the ratio of the resultant LU1 to LU2. The reason why the hologram 101 is placed on the black plate 102 is that any measurement errors caused by the background that is otherwise visible through the hologram 101 when the light reproduced from the hologram 101 are measured becomes.
The full width of the reproduction angle at half maximum (FWHM) of the diffracted light intensity used herein is the whole width of the reproduction angle at half maximum of the intensity of the diffracted light, and refers to it when the intensity of the diffracted light diffracted light is expressed by a function of an angle β between a normal to the hologram and a straight line connecting the base of the normal to the hologram with the measuring device, obtaining an angular range by doubling the angle at which the intensity of the diffracted Light is equal to half of a maximum value thereof. Fig. 26B is a graph showing the diffracted light intensity as a function of the angle β, with the whole width at half maximum (FWHM) being graphically assigned. The intensities of the diffracted light I at the angles ± γ are half of the maximum, as shown in Fig. 26B. The whole width at half maximum is therefore 2γ. The whole width of the intensity of the diffracted light at half maximum shall be called later than the whole width of the reproduction angle at half maximum of the intensity of the diffracted light.
The diffusion angle used here is determined when a collimated laser beam having a peak intensity within a range of visible wavelengths is incident on a diffusion object, referring to an angle at which the luminance of the diffracted light is half the center luminance. A diffusion range can be set 8 with the following relationship. (Diffusion area) * 2 x (distance to the illuminated area) x (tangent of the diffusion angle)
The angle used here is not a solid angle but a flat angle, unless otherwise specified. For example, the angle of incidence of the illumination light incident on a hologram relates to an angle defined in a plane containing a normal to the hologram and a straight line connecting the base of the normal to the hologram with the light source Normal is measured.
In accordance with at least one of the above-described embodiments, a hologram recording medium on which character information, bar code information and other information are recorded as a hologram can reproduce the information without generating multiple images. BRIEF DESCRIPTION OF THE DRAWINGS In the drawings:
Fig. 1 is a simplified diagram showing an exemplary structure of an apparatus for producing a hologram recording medium;
Figs. 2A and 2B show the intensity of the diffracted light of an image reproduced from a hologram recording medium;
Figs. 3A and 3B show the intensity of the diffracted light of an image reproduced from a hologram recording medium; Figs.
4A and 4B show the intensity of the diffracted light of an image reproduced from a hologram recording medium;
Fig. 5 is a simplified diagram showing the viewing angle at which a reproduced image can be viewed;
6A to 6F are simplified views showing reproduced images with the direction from which a hologram recording medium is viewed, wherein the orientation of the hologram recording medium is fixed and the direction in which the illumination light is incident is changed;
7A to 7F are simplified views in which reproduced images are shown with the direction in which the illumination light impinges, the orientation of a hologram recording medium being fixed, and the direction from which the hologram recording medium is viewed being changed ;
8A to 8F are simplified views showing reproduced images in which the direction in which the illumination light is incident and the direction from which a hologram recording medium is viewed are fixed and the orientation of the hologram recording medium is changed;
Fig. 9 is a simplified diagram showing a second exemplary construction of the apparatus for producing a hologram recording medium;
10A and 10B show an exemplary structure of the hologram recording medium,
Fig. 11 shows another exemplary construction of the apparatus for producing a hologram recording medium;
12A and 12B show an exemplary structure of an apparatus for reproducing a hologram recording medium;
Figs. 13A and 13B also illustrate the exemplary structure of the apparatus for reproducing a hologram recording medium; Figs.
Fig. 14A is a simplified view showing how an image is reproduced when a single light emitting diode light source illuminates a hologram recording medium; Fig. 14B is a simplified view showing a reproduced image which is then seen when character information recorded on the hologram recording medium is reproduced by illuminating the hologram recording medium at a predetermined angle, and FIG. 14C is a simplified view showing a reproduced image in FIG when a two-dimensional bar code recorded on the hologram recording medium is reproduced by illuminating the hologram recording medium at a different predetermined angle;
Fig. 15A is an example of a light source for illuminating a hologram recording medium; Fig. 15B is a simplified view showing a reproduced image which is seen when a character information recorded on the hologram recording medium passes therethrough Fig. 15C is a simplified view showing a reproduced image which is seen when a two-dimensional bar code recorded on the hologram recording medium is displayed is reproduced by illuminating the hologram recording medium at a different predetermined angle;
Fig. 16A is an example of a light source for illuminating a hologram recording medium; Fig. 16B is a simplified view showing a reproduced image which is seen when a piece of information recorded on the hologram recording medium passes therethrough Fig. 16C is a simplified view showing a reproduced image which is seen when a two-dimensional bar code recorded on the hologram recording medium is reproduced is reproduced by illuminating the hologram recording medium at a different predetermined angle;
Fig. 17A is an example of a light source for illuminating a hologram recording medium; Fig. 17B is a simplified view showing a reproduced image which is seen when a hologram recording medium is shown.
11
Character information recorded on the hologram recording medium is reproduced by illuminating the hologram recording medium at a predetermined angle, and FIG. 17C is a simplified view showing a reproduced image, which is then seen; when a two-dimensional bar code recorded on the hologram recording medium is reproduced by illuminating the hologram recording medium at a different predetermined angle;
Fig. 18A is an example of a light source for illuminating a hologram recording medium; Fig. 18B is a simplified view showing a reproduced image which is seen when character information recorded on the hologram recording medium passes therethrough Fig. 18C is a simplified view showing a reproduced image which is seen when a two-dimensional bar code recorded on the hologram recording medium is reproduced is reproduced by illuminating the hologram recording medium at a different predetermined angle;
Figs. 19A and 19B are simplified views showing an example in which a hologram recording medium on which many pieces of 2D information are recorded is attached to a product package;
20A and 20B are simplified views showing an example of how to read out individual ID information formed as a bar code recorded on a hologram recording medium;
Figs. 21A and 21B are simplified views showing an example in which a digital camera captures an image of a hologram recording medium having many pieces of 2D information recorded on it;
FIGS. 22A to 22D are exemplary high frequency patterns;
FIG. 23 shows a simplified section through an edge-illuminating background light; FIG.
Figs. 24A and 24B show a second exemplary construction of the apparatus for reproducing a hologram recording medium;
Figs. 25A and 25B are also the second exemplary construction of the apparatus for reproducing a hologram recording medium; Figs.
Fig. 26A is a simplified view showing a method of measuring the intensity of the diffracted light; and Fig. 26B is a graph showing the diffracted light intensity as a function of an angle β and the full width at half maximum associated with the diagram;
Figs. 27A and 27B are simplified diagrams describing an optical system used when information is recorded on a hologram recording medium and recorded on the hologram recording medium
Information is reproduced;
Fig. 28 is a sectional view showing an example of a hologram recording medium;
Figs. 29A to 29C are simplified diagrams showing a method such as a
Photopolymerization material is exposed; and Fig. 30 is a simplified diagram schematically showing a contact copying apparatus.
DETAILED DESCRIPTION
Now, embodiments of a hologram recording medium and a method for the production thereof, a hologram reproducing apparatus and a hologram reproducing method will be described. The description will be in the order now given. ≪ 0th Volume hologram > [Principle of Recording and Playback] 13 * «* * [Example of Hologram Recording Medium] [Reproducing with a contact copy method] < 1. First embodiment > [Exemplary structure of the manufacturing apparatus] (Reference light optical system) (Objective light focusing optical system) (Object light) [Hologram recording medium on which 2D information is recorded] (reproduction of the recorded information) (Control of the recorded information) Viewing angle) (locating 2D information) (changing the reproduced image) [Second Exemplified Construction of First Embodiment] [Third Exemplary Construction of First Embodiment] < 2. Second Embodiment > [Exemplary Construction of Manufacturing Apparatus] [Second Exemplified Construction of Second Embodiment] < 3. Third embodiment > [Exemplary structure of a hologram reproducing apparatus] (viewing a hologram on which 2D information is recorded) (illuminating light source) (detecting holographic 2D information)
Using an imaging device) {high-frequency pattern) [Second exemplary construction of the third embodiment] < 4. Variants >
The following embodiments are preferred specific examples. In the following description in which a variety of technically preferred limitations are introduced, the examples of a hologram recording medium and a method of manufacturing the same, a hologram reproducing apparatus, and a hologram reproducing method are not the following ones
Embodiments are limited unless otherwise expressly stated that the present disclosure is limited to the embodiments. ≪ 0th Volume hologram >
Before describing the embodiments, a volume hologram will be summarized to facilitate understanding of the description.
[Principle of recording and playback]
In a volume hologram, an interference pattern in terms of refractive index differences is recorded on a recording layer, as described above. An interference pattern is recorded by illuminating a hologram recording medium with reference light and object light containing information of images to be recorded simultaneously but from different directions.
Now, referring to Figs. 27A and 27B, an optical system which is used when information is recorded on a hologram recording medium 101 and when the information recorded on the hologram recording medium 101 is reproduced will be described ,
At the time of recording, the reference light RL is incident on the hologram recording medium 101 at an incident angle 9R and an object light OL on the opposite side of the hologram recording medium 101 at an incident angle θo, as shown in Fig. 27A. An interference pattern formed by the reference light RL and the object light OL is recorded on the hologram recording medium 101.
When the hologram recording medium 101 on which the interference pattern has been recorded is illuminated with illuminating light IL at an angle of incidence α (a = 9r), as shown in Fig. 27B, the illuminating light IL is diffracted in the hologram recording medium 101, with the illuminating light IL
Reproduction light PL exits from the hologram recording medium 101 at an exit angle β (β = 180 ° -θο}, and a viewer in the direction of the object light OL can therefore see a reproduced image.
When the recording shown in Fig. 27A is performed, the incident angle Br of the reference light is adjusted to set a preferred illumination angle at which the hologram recording medium is illuminated, i. the angle oi. Further, the incident angle θo of the object light is adjusted to set a central angle at which the luminance of the reproduced light is maximized, i. the angle ß.
[Example of hologram recording medium]
An example of a hologram recording medium 1 serving to record image information will now be described. The hologram recording medium 1 comprises a film base 1a formed in a band shape, a photopolymer layer 1b formed of a photopolymerization material formed on the film base 1a, and a cover film 1c laminated on the photopolymer layer 1b, as shown Fig. 28 shows. The hologram recording medium 1 constitutes a so-called recording medium based on the application of transparencies.
The photopolymerization material is formed from a monomer M which is distributed in an initial state in a matrix polymer as shown in Fig. 29A. When the photopolymerization material is illuminated with light LA having a thickness in the range of about 10 to 400 mJ / cm 2, the monomer M is polymerized in the part exposed to the light, as shown in Fig. 2B , The monomer M around the polymerized part then moves in as the polymerization proceeds, changing the concentration of the monomer M in the material. This modulates the refractive index in the material. The entire material is then illuminated with ultraviolet or visible light LB having a thickness of about 1000 mJ / cm 2, as shown in Fig. 29C, thus terminating the polymerization of the monomer M. , As already described above, the refractive index of a photopolymerization material changes in accordance with light incident thereon, whereby an interference pattern is generated when the reference light interferes with the object light that can be recorded in the form of a change in refractive index.
In order to fix the image recorded on the hologram recording medium 1 with a higher value of refractive index modulation in the photopolymer layer 1b, a heating step may be added to the hologram recording medium 1.
The hologram recording medium 1 composed of the above-described photopolymerization material typically does not require a developing process after being exposed. Therefore, the use of the hologram recording medium 1 having a photosensitive member made of the photopolymerization material enables the structure of a hologram manufacturing apparatus and a hologram duplicating apparatus to be simplified.
[Reproduce with a contact copy operation]
A volume hologram on which image information has been recorded may be prepared as described above. Further, the image information recorded in the volume hologram can be reproduced, and the reproduced light is used as object light to copy the image information to another hologram recording medium. The method is called contact copying because a hologram on which the image information has been recorded is used as the original, and the image information is recorded on another hologram recording medium in close contact with the original. Reproduction based on contact copying will be referred to as contact copying later.
Fig. 30 shows a simplified representation, in which a contact printing device is shown in simplified form. In the contact copying apparatus, a laser beam from a 17
Laser light source III is enlarged with a spatial filter 117, wherein the magnified light is incident on a collimating lens 119, as shown in FIG. A hologram
Recording medium 101 containing a photosensitive material and a hologram original 511 are irradiated with the (S-polarized) laser beam which has been collimated by the collimating lens 119.
The hologram original 511 is, for example, a Lippmann hologram. The hologram recording medium 101 having a photosensitive material layer and the hologram original 511 are arranged so as to come in close contact with each other directly or through a liquid with which the photosensitive material is applied
Refractive indices (referred to herein as index matching liquid). An interference pattern formed when light diffracted in the hologram original 511 interferes with the incident laser light is recorded on the hologram recording medium 101. & Lt -1. First embodiment >
Now, an embodiment will be described.
In accordance with a first embodiment, many pieces of image information are recorded on a hologram recording medium. Each of the many pieces of image information is focused directly on an area of the hologram recording medium and recorded on the hologram recording medium by applying object light from a predetermined direction via an optical focusing system having a predetermined focal length
Diffusion angle delivers.
The hologram recording medium of the first embodiment can thus record many pieces of image information, allowing a viewer to read each of the many pieces of image information from a given viewing direction within a predetermined one
Angle range can be considered. Further, in the first embodiment, the hologram recording medium can record many pieces of image information expressed in a planar form, for example, characters and bar codes (hereinafter suitably referred to as 2D information, wherein three-dimensional image information in spatial form later fits as 3D information is designated), and correspondingly sharp images play.
[Exemplary Construction of Manufacturing Apparatus]
A first method for producing a hologram
Recording medium on which 2D information is holographically recorded will now be described first in conjunction with FIG.
Fig. 1 shows an exemplary structure (a first exemplary construction) of an apparatus for producing a hologram recording medium. In the exemplary structure shown in FIG. 1, a laser light source 11, a shutter Sh, a half-wave plate 13, and a polarizing beam splitter 15 are arranged in this order. The laser beams split by the polarizing beam splitter pass through a reference light optical system and an object light focusing optical system, and are incident on a hologram recording medium 1. (Optical system for the reference light)
In the first exemplary construction, two optical systems for the reference light are provided, as shown in FIG. That is, one of the laser beams divided by the polarized beam splitter 15 and directed to the reference light optical system is reflected by a mirror 23ra and divided by a half-silvered mirror 43 into two laser beams. One of the split laser beams travels along a first optical path and impinges on the hologram recording medium 1, while the other laser beam travels along a second optical path and impinges on the hologram recording medium 1.
The first optical path has a shutter Shi, a spatial filter 17ri and a collimating lens 19 ^ arranged in 19 * β * * of this order. The second optical path has a shutter Sh2, a mirror 23rb and 23rc, a spatial filter 17r2 and a collimation lens 19r2 arranged in this order. The incident angles 9rx and 9r2 of the reference light beams are set to 45 ° and 22.5 °, respectively. (Optical focusing system for the object light)
The object light focusing optical system includes a spatial filter 17o, a collimating lens 19o, a mirror 23o, a diffuser 25, a liquid crystal panel 27, a polarizer 29, a lens 31, a diaphragm 33, and a lens 35 arranged in this order. The liquid crystal panel 27 is connected to a liquid crystal driver (not shown) such as one
Microcomputer. The polarizer 29 is located on a light exit side of the liquid crystal panel 27. The optical elements disposed along the optical path from the mirror 23o to the hologram recording medium 1 are fixed to a rail or any other support member at predetermined positions.
The object light is incident on the hologram recording medium 1 approximately at right angles. That is, the incident angle θo of the object light is set to, for example, about 0 ° ± 5 °. The reason for this is that the luminance of the reproduced 2D information in the vicinity of the direction of a normal to the recording surface of the hologram recording medium can be maximized.
The image information is recorded on the hologram recording medium 1 as follows (reference light).
First, the shutter Shi is brought into an open position and the shutter Sh2 in a closed position. Of the
Laser beam from the laser light source 11 passes through the
Half-wave plate 13 and impinges on the polarizing beam splitter 15. The half-wave plate 13 rotates the
Polarization plane of the laser beam by 90 °. A part of the. * 20
Laser beam is reflected by the polarizing beam splitter 15 and enlarged by the spatial filter 17ri.
The laser beam from the spatial filter 17rx (i.e., the reference light) is incident on the collimating lens 19ri. The laser beam is then collimated by the collimating lens 19rx, and the hologram recording medium 1 having a photosensitive material layer is illuminated with the collimated (Ξ-polarized) laser beam. (Object light)
The laser beam which has passed through the polarizing beam splitter 15 is incident on the spatial filter 17o. Of the
Laser beam magnified by the spatial filter 17o is collimated by the collimating lens 19o and incident on the mirror 23o.
The laser beam reflected by the mirror 23o passes through the diffuser 25 and impinges on the liquid crystal panel 27, which functions as a spatial light modulator. The liquid crystal driver described above displays on the liquid crystal panel 27 an image indicating 2D information to be recorded. The liquid crystal panel 27 rotates the polarization plane of the laser beam and the polarizer 29 transmits a required S-polarized portion. The laser beam scattered by the diffuser 25 is narrowed by the diaphragm 33. This sets the viewing angle at the time of viewing.
The light that carries the 2D information that comes from the
Liquid crystal plate 27 has been generated, and has passed through the polarizer 29, then applies to the hologram recording medium 1 via an optical focusing system, which is formed by the projection lens 31, the diaphragm 33 and the projection lens 35.
Thus, on the hologram recording medium 1 a
Interference pattern recorded by the incident
Laser beam, which is the reference light, and that laser beam is formed, which contains the 2D information and which is the object light. 21 • · »
In an embodiment for producing a hologram recording medium, the diffusion angle provided by the diffuser 25 preferably has a smaller absolute value. Considering that an image of the recorded 2D information is captured in the direction of a normal on the recording surface of the hologram recording medium, the diffuser 25 preferably provides a diffusion angle that causes the whole width of the intensity of the diffracted light to be at half maximum, which carries the reproduced 2D information is equal to 8 ° or smaller. An experiment in which a typical diffusion light source has been used to illuminate a hologram recording medium has shown that when the full width of the diffracted light intensity at half maximum is equal to or smaller than 8 °, many pieces of identification information come together with an excellent sharpness and uniformity over an area over which the identification information has been recorded (for example, 15 mm square).
Specifically, in the production method of the medium, the absolute value of the diffusion angle is preferably equal to or less than 7 °, more preferably 3 ° or smaller. The reason for this is that the viewing angle over which the information recorded on the hologram recording medium is reproduced changes with the diffusion angle provided by the diffuser 25, as will be described later.
The reason why the diffusion angle is set to be smaller than a whole target width at half maximum of the intensity of the diffracted light is that the degree of diffusion at the time of recording differs from the degree of diffusion at the time of reproduction. The reason for this is diffractions occurring in the hologram recording medium itself, instabilities of polymerization when interference fringes and hence scattering are formed, and other factors.
On the other hand, the diffuser may be constructed so as to scatter light by about ± 20 ° only in the direction perpendicular to the illumination plane of Fig. 1, but scatters no light in the 22 ° direction of Fig. 1 at all. In another alternative, the diffuser 25 may be omitted if necessary.
In the exemplary structure shown in Fig. 1, the laser beam, which is the light object containing the 2D information, has a diffusion angle ± 5 generated by the diffuser 25 near the vicinity of the diffuser
Liquid crystal plate 27 and the diaphragm 22 is located.
After the 2D information (the first 2D information) has been recorded, on the hologram
Recording medium 1 recorded another part of a 2D information (the second 2D information), which is different from the first 2D information.
Before the second 2D information is recorded, the shutter Shx is brought to the closed position and the shutter Sh2 is brought to the open position. The spatial filter 17r2 enlarges the laser beam when the shutter Sh2 is in the open position at the time of exposure. The laser beam from the spatial filter 17r2 (i.e., the reference light) is incident on the collimating lens 19r2. (S-polarized)
Laser beam aligned in parallel by the collimating lens 19r2 then falls on the hologram
Recording medium 1 having a layer of a photosensitive material. The incident angle Θγ of the reference light to be incident on the hologram recording medium 1 is preferably changed while the incident angle θo of the object light to be incident on the hologram recording medium 1 remains unchanged. The reason is that it is considered that an image of the recorded 2D information is caught in the direction of a normal on the recording surface of the hologram recording medium, the luminance of the reproduced 2D information in the vicinity of the direction of the normal to the recording surface of the Hologram recording medium is preferably maximized.
The incident angle θΓι of the reference light is set to 45 ° when the first 2D information is recorded, 23 while the incident angle θr2 is preferably set to a value in a range from 10 ° to 35 ° when the second 2D information is recorded. For example, the reason is not only that a reproducing apparatus having a light source that illuminates the hologram recording medium from a predetermined direction, and an imaging device can be made smaller because the light source and the imaging device can be arranged to be Do not disturb each other, and also the strength of crosstalk between the first 2D information and the second 2D information can be reduced.
The reason why one of the incident angles of the reference light used for recording the first 2D information is set to 45 ° is that the requirement of the incident angle is in many cases determined by the premise that a hologram is illuminated generally with an obliquely downwardly directed light at an angle of about 45 ° + 8 °, the angle of incidence being determined by simply following this agreement. The reason why the construction of a hologram is generally performed due to the angle as described above is that a hologram is in many cases illuminated with a downward light, for example, light from a ceiling lamp or sunlight wherein the downwardly directed illumination light incident at an angle less than the above-described value is reflected directly from the hologram to the viewer's eyes, the reflected light making it difficult for the viewer to see the hologram during an angle of incidence of the downwardly directed illumination light, which is greater than the value described above, increases the surface reflection, but reduces the degree of utilization of the light.
Alternatively, the incident angle θr2 is preferably set to a value in the range of 55 ° to 80 °. Again, the reason for this is that the amount of crosstalk between the first 2D information and the second 2D information can be reduced. • * * * · ''% 't * * * «- * * ·« · »t • * · · · *», ··· «· *** ♦♦ * * * ···« · * »I» * * * «* ·« »· 24
The liquid crystal panel 27 shows an image indicating the second 2D information, and the hologram
On drawing medium 1 is illuminated with the reference light and the object light. That is, an interference pattern is recorded on the hologram recording medium 1 constituted by the incident laser beam which is the reference light and the laser beam which contains the second 2D information and which is the object light is.
In the example shown in Fig. 1, two optical paths of the reference light are provided. Alternatively, three or more optical paths of the reference light may be provided, the exposure being performed in a plurality of times corresponding to the number of optical paths of the reference light. When the above-described steps are repeated, many different pieces of image information can be recorded on the hologram recording medium. In this case, for recording the individual pieces of image information, the diffuser 25 and the diaphragm 33 may be changed so as to change the viewing angles over which the individual images are reproduced, or to change the wavelength of the laser beam used.
[Hologram recording medium on which 2D information is recorded]
On the hologram recording medium manufactured by using the manufacturing method described above, many pieces of information are recorded. When the hologram recording medium is illuminated with light from a predetermined angle, a corresponding part of the many pieces of the recorded information is reproduced, and a reproduced image with the full width of the diffracted light intensity at half maximum is set. The many parts of the information are reproduced so that no multiple images are generated. (Playback of the recorded information)
Figures 2A and 2B, 3A and 3B, and 4A and 4B describe the 25 * *. * * * * * 4
Intensity of the diffracted light of an image reproduced from a hologram recording medium Is. Now, suppose that the hologram recording medium ls has image information S and 2D information PI superimposed and recorded thereon, and that the image information Ξ is recorded with the diffusion angle δ of the object light, which is not particularly limited the 2D information PI is recorded at the specified diffusion angle δ of the object light. Further, let it be assumed that the incident angle Θ ri of the reference light used to record the image information S is 45 °, and that the incident angle 0r2 of the reference light used to record the 2D information PI is the same 22 ° is. Furthermore, let it be assumed that the incident angle θo of the object light is about 0 ° in both cases.
Fig. 2A shows a case where the hologram recording medium ls is illuminated with white illumination light IL at an angle of a = 45 °. FIG. 2B shows the intensity of the diffracted light of a reproduced image captured by an imaging device 71.
Fig. 2B is a graph showing the intensity of the diffracted light of a reproduced image. In Fig. 2, the dashed line Is represents the intensity of the diffracted light associated with the image information S, while the solid line IPi represents the intensity of the diffracted light associated with the 2D information PI.
Since the incident angle α of the illumination light IL is equal to 45 °, a peak of the intensity of the diffracted light associated with the image information S is in the vicinity of the direction of a normal (β = 0 °) on the recording surface of the hologram recording medium ls this Fig. 2B shows. The near range used here is preferably in the range of -10 ° to + 10 °.
This means that a viewer, when he is facing the hologram recording medium ls and looking at it, can recognize the image information S. On the other hand, the peak of the intensity of the diffracted light associated with the 2D information PI does not lie in the vicinity of the direction of the normal (β = 0 °) on the recording surface of the hologram recording medium ls. Thus, the 2D information PI does not prevent the viewer from seeing the image information S.
Pig. 3A shows a case where the hologram recording medium 1s is illuminated with white illumination light IL at an angle of a-22 °. FIG. 3B shows the intensity of the diffracted light of a reproduced image captured by the imaging device 71.
Fig. 3B is a graph showing the intensity of the diffracted light of a reproduced image. In Fig. 3B, the dashed line Is indicates the intensity of the diffracted light associated with the image information S, and the solid line IPi indicates the intensity of the diffracted light associated with the 2D information PI.
Since the incident angle α of the illumination light IL is equal to 22 °, a peak of the intensity of the diffracted light associated with the 2D information PI is in the vicinity of the direction of a normal (β = 0 °) on the recording surface of the hologram recording medium ls as shown in Fig. 3B. That is, when the viewer is facing and looking at the hologram recording medium ls, the viewer can recognize the 2D information PI. The whole width of the intensity of the diffracted light at half maximum associated with the 2D information PI is preferably 8 ° or smaller, as shown in FIG. 3B.
Next, let us consider a hologram recording medium ls on which, instead of the 2D information P1, a 2D information P2 is recorded by that
Incident angle Gr of the reference light was set to 67 °.
Fig. 4A shows a case where the hologram recording medium ls is illuminated with white illumination light IL at an angle of a = 67 °. FIG. 4B shows the intensity of the diffracted light of a reproduced image captured by the imaging device 71.
Fig. 4B is a graph showing the intensity of the diffracted light of a reproduced image. In Fig. 4B, the dashed line Is indicates the intensity of the diffracted light associated with the image information S, and the solid line IP2 indicates the intensity of the diffracted light associated with the 2D information P2.
Since the incident angle α of the illumination light IL is 67 °, a peak of the intensity of the diffracted light associated with the 2D information P2 is in the vicinity of the direction of a normal (β = 0 °) on the recording surface of the hologram recording medium as shown in Fig. 4B. That is, when the viewer is facing the hologram recording medium and viewing it, the viewer can recognize the 2D information P2. The whole width of the intensity of the diffracted light at half maximum associated with the 2D information P2 is preferably equal to or smaller than 8 °, as shown in FIG. 4B.
The incident angles 0r of the reference light beams used for recording the corresponding pieces of information may alternatively be set as follows: one of the incident angles 0r is equal to 45 °, while the other incident angle Gr is equal to -45 ° (0r = 315 °) , In this case, since the amount of crosstalk between reproduced images is small, corresponding pieces of information can be recorded, and the diffusion angles provided by the object light focusing optical system are not necessarily fixed, provided that the recorded information is not read out by machine becomes.
When a hologram recording medium on which information is recorded with 0r set at 45 ° and -45 ° as the upper and lower parallax direction of the hologram recording medium is hung on a wall or other similar surface, the hologram For example, light is illuminated on a drawing medium with light from a ceiling light, whereby one of the pieces of information is reproduced. Thereafter, the hologram recording medium is hung upside down on the wall, with the other information 28 "* V"
* i t »*» φ • «* * * * ·« t I «· f- * * * *» «is played back. When it is difficult to hang the hologram recording medium upside down (for example, when the hologram recording medium is attached to a large, heavy body), the other information can be easily viewed by tilting the hologram 45 degrees upward is illuminated with light from a flashlight or other suitable device that emits light that is brighter than the light from the ceiling light.
In both cases described above, one of the intensities of the diffracted light in the vicinity of the direction of the normal to the hologram recording medium is preferably at least five times larger than the intensity of the other diffracted light. In this way, each of the reproduced pictures can be clearly recognized. (Control of the viewing angle)
As described in conjunction with FIGS. 2A and 2B, FIGS. 3A and 3B and FIGS. 4A and 4B, by setting the diffusion angle provided by the object light focusing optical system, a hologram recording medium can be manufactured so that information is recorded by an observer only within a defined angular range. At the time of reproduction, a reproduced hologram recording medium 1 is illuminated with the illumination light IL at an angle of incidence α, as shown in FIG. The viewing angle at which an image reproduced from the hologram recording medium is viewed has a width of +5. (Localizing the 2D information)
In accordance with the exemplary construction of Fig. 1, image information is recorded on the hologram recording medium 1 expressed in a plane form (2D information). The 2D information is formed, for example, by characters, numbers, symbols, figures, patterns, one-dimensional bar codes, two-dimensional bar codes, or any combinations thereof. The 2D * * Μ 1 < , »- * · -. - i * »* · · I. , 4 ·· * · «. , ·, *** · »* * *« t · '· *. , · 29
Information is directly placed at a very flat location on the recording surface of the hologram recording medium 1 by fixing the diffusion angle that the object light optical focusing system supplies. The depth at which the 2D information is arranged can be arbitrarily set, preferably to 2 mm or less, by using image processing or adjusting the position of the diffuser.
If the location at which the image information is arranged is far from the recording surface, multiple images are disadvantageously reproduced when a diffusion light source illuminates the hologram recording medium, resulting in deterioration in the sharpness of a reproduced image. In this case, a punctiform light source enables crisp reproduction of the 2D information, while reproduced character information disadvantageously generates multiple images when the hologram recording medium is viewed in, for example, cloudy weather. This means that no sharp image is reproduced, making it difficult to machine-read the 2D information.
In the example described above, the image information on the hologram recording medium 1 is not recorded in a contact copying operation. The reason for this is that, for example, when character information is recorded in plane form in a contact printing method, the fact that a hologram original has a certain thickness causes the character information to be disadvantageous at a certain depth from the recording surface of the hologram Recording medium is arranged.
As described above, in holographic recording of 2D information, it is effective to set the diffusion angle provided by the object light focusing optical system, that is, the viewing angle at which a reproduced image of the 2D information is viewed is set to a small value.
30 (Changing the Played Image)
Figs. 6A to 6F, 7A to 7F and 8A to 8F describe the relationship of the direction in which the illuminating light is incident, the direction in which a hologram recording medium is viewed, and the orientation of the hologram recording medium to a reproduced image. In Figs. 6A to 6F, 7A to 7F and 8A to 8F, 2D information is recorded on the hologram recording medium 1 constituted by a two-dimensional bar code, a character information and a one-dimensional bar code. The parts of the 2D information are recorded with the incident angles Gr of the reference light beams which are different from each other, and the whole width of the diffracted light intensity at half maximum of each reproduced image is equal to or smaller than 8 °.
Figs. 6A to 6F show reproduced images in the direction from which the hologram recording medium is viewed, the orientation of the hologram recording medium being fixed, and the direction in which the illumination light is irradiated being changed. First, the direction in which the illumination light IL is incident, the direction D from which the hologram recording medium 1 is viewed, and the orientation of the hologram recording medium 1 are set as shown in Fig. 6A. When the hologram recording medium is viewed in this state, the two-dimensional bar code shown in Fig. 6D can be seen. When the direction in which the illumination light IL is incident is changed as shown in Fig. 6B, the image reproduced from the hologram recording medium 1 changes to the character information shown in Fig. 6E. Further, when the direction in which the illumination light IL is incident changes as shown in Fig. 6C, the reproduced image changes to the one-dimensional bar code shown in Fig. 6F.
As described above, the 2D information reproduced from the hologram recording medium 1 can be changed in accordance with the direction in which the illumination light IL is incident. 31 • «« * '· * 4 · · «· φ
7A to 7F show reproduced images in which the direction in which the illumination light is incident and the orientation of the hologram recording medium are fixed, and the direction in which the hologram image is changed is shown.
On drawing medium is considered. When the direction in which the illumination light IL is incident, the direction D from which the hologram recording medium 1 is viewed, and the orientation of the hologram recording medium 1 change as shown in any of Figs. 7A, 7B and 7C, change the reproduced image as shown in the corresponding Fig. 7D, 7E and 7F.
FIGS. 8A to 8F show reproduced images where the direction in which the illuminating light is incident and the direction from which the hologram recording medium is viewed are fixed and the orientation of the hologram is shown.
Recording medium is changed. When the direction in which the illumination light IL is incident, the direction D from which the hologram recording medium 1 is viewed, and the orientation of the hologram recording medium 1 change, as any of Figs. 8A, 8B and 8C, the reproduced image changes as shown in the corresponding FIGS. 8D, 8E and 8F.
As described above, from the direction in which the illuminating light IL is incident from the direction D from which the hologram recording medium 1 is viewed, and from the orientation of the hologram recording medium 1, two are fixed thereto and the rest is changed, information reproduced from a hologram recording medium 1 may be changed.
Second Exemplified Construction of First Embodiment
9 shows a second exemplary construction of the device for producing a hologram
Recording medium. The second exemplary construction differs from the first exemplary construction in which two optical paths of the reference light are provided by providing two optical paths of the object light. That is, the half-silvered mirror 43 is located in the optical path 32 of the laser beam which has passed through the polarizing beam splitter 15 to further divide the laser beam into first and second split laser beams. In the second exemplary construction, two optical focusing systems are thus provided for the object light.
The laser beam which has passed through the half-silvered mirror 43 strikes a mirror 23, as shown in FIG. The reflected laser beam from the mirror 23 forms the second split laser beam.
The first split laser beam passes through a diffuser 25a and impinges on a liquid crystal panel 27a (having a polarizer), as in the first exemplary construction. An image bearing 2D information and displayed on the liquid crystal panel 27a is focused on a hologram recording medium 1 through an optical focusing system (projection lenses 31a and 35a and a diaphragm 33a).
On the other hand, the second split laser beam passes through the diffuser 25b, impinging on a liquid crystal panel 27b (having a polarizer). An image carrying 2D information and displayed on the liquid crystal panel 27b is focused on the hologram recording medium 1 through an optical focusing system (projection lenses 31b, 35b and diaphragm 33b).
The incident angle of the light carrying the 2D information and generated by the first divided laser beam with respect to the hologram recording medium 1 differs from the angle of incidence of the light carrying the 2D information and the second divided laser beam with respect to the hologram Recording medium 1 is generated. A viewpoint from which the 2D information generated by the liquid crystal panel 27a is viewed can thus be different from a viewpoint from which the 2D information generated by the liquid crystal panel 27b is viewed.
The hologram recording medium 1 is therefore irradiated simultaneously with the two divided laser beams. On the other hand, 33 9 < • »the hologram recording medium 1 can be irradiated with the two divided laser beams in succession. In another alternative, three or more split laser beams may be used.
In accordance with the second exemplary construction of the first embodiment, two kinds of 2D information viewed by two viewpoints can be simultaneously recorded on the hologram recording medium 1.
Third Exemplary Construction of First Embodiment
Figs. 10A and 10B show an exemplary structure of the hologram recording medium. A third exemplary construction differs from the first exemplary construction in that a hologram recording medium on which 2D information is recorded is a transparent volume hologram.
Figs. 10A and 10B show an example in which a hologram recording medium 1 is attached to a display of a cellular phone 73. For example, two pieces of 2D information are recorded on the hologram recording medium 1. One of the two parts of the 2D information is a character information, while the other part is a combination of a character information and a one-dimensional barcode.
The reproduced 2D information can be changed by changing the angle at which the display is viewed, as shown in FIGS. 10A and 10B. The intensity of the diffracted light of a reproduced image viewed by a viewer who is facing the display can be set to a small value by appropriately adjusting the incident angle of the reference light at the time of recording. Therefore, the hologram recording medium 1 mounted on the display does not hinder the user of the cellular phone 73 when operating the cellular phone.
Therefore, many pieces of information recorded on the hologram recording medium 1 can be alternately reproduced by illuminating the hologram recording medium 1 from certain directions. Therefore, a hologram recording medium 1 thus constructed can be mounted, for example, on a transparent display window, wherein the
Illumination beam can change in a variety of directions, whereby the shop window itself can become an advertising medium that attracts consumers.
In accordance with the third exemplary construction of the first embodiment, the hologram recording medium does not prevent the display of information, or it can on a subject to which the hologram recording medium is mounted so that it can be viewed, a variety of objects with decorative Display forms, management information, product information or other information.
The article to which the hologram recording medium 1 is attached may be not only the display of a mobile phone but also, for example, the display of a personal computer, a smartphone, a minicomputer or a mini-data computer, and a portable video game console. Furthermore, the object on which the hologram
Attached to the drawing medium 1, an ID photo, a product packaging, a business card, a student card, or any other object. ≪ 2nd Second embodiment >
Now, a second embodiment will be described.
In accordance with a second embodiment, many pieces of image information are recorded on a hologram recording medium. The many pieces of image information include 3D information and 2D information. In the many pieces of image information, the 2D information is focused directly on the surface of the hologram recording medium. In the many pieces of image information, the 2D information on the hologram recording medium is conveyed from a predetermined direction by using an object light from a predetermined direction
The optical focusing system records a given diffusion angle.
The 3D information and the 2D information may therefore be recorded on the hologram recording medium, the 2D information being visible from a given viewing direction within a predetermined angular range.
[Exemplary Construction of Manufacturing Apparatus]
Now, referring to Fig. 11, a method of manufacturing a hologram recording medium on which 3D information and 2D information are recorded will be described.
Fig. 11 shows an exemplary structure of the apparatus for producing a hologram recording medium. In the exemplary construction shown in Fig. 11, 3D information recorded on a hologram original 51 is copied onto a hologram recording medium in a contact copying operation, further recording 2D information as superposed additional information. In the exemplary construction of Fig. 11, the 2D information is recorded as additional information using a laser beam different from a laser beam used in the contact copying operation.
A light source (not shown) of a copying laser beam LC, rollers 61, 63 and 65, an exposure member 67 and a UV fixing member 69 are arranged in this order, as shown in FIG. The hologram original 51 is mounted around the roller 63. The hologram original 51 includes, for example, horizontal continuous parallax images.
A hologram recording sheet If is fed from a roller (not shown) and transported between the rollers 61 and 63, the rollers 65 and 63, the exposure member 67 and the UV fixing member 69 in this order. The hologram recording film is produced by applying a photosensitive material to a transparent base sheet. 36
The hologram recording sheet 1f supplied from the feed roller is wound around the roller 63. The hologram recording film 1f in close contact with the hologram original 51 is irradiated with the copy laser beam LC, and the hologram in the hologram original 51 is copied onto the hologram recording film 1f. Specifically, when the supply of the hologram recording film 1f is stopped, a shutter associated with the light source (not shown) of the copying laser beam LC is simultaneously opened with the copying laser beam LC applied.
The hologram recording film 1f to which the hologram has been copied is transported to the exposure part 67 where the 2D information is superimposed and recorded. The structure for the recording of the 2D-Inf ormation can be made as was the case in the first embodiment.
The hologram recording film 1f on which the 3D information and the 2D information are recorded is transported from the exposure part 67 to the UV fixing part 69. Alternatively, the steps described above may be performed as follows: the 2D information is first drawn up; then the hologram is copied in a contact copying process, and the fixation is performed.
[Second Exemplary Construction of Second Embodiment]
A second exemplary construction of the second embodiment differs from the construction shown in Fig. 1 in that a hologram recording medium on which 3D information has been recorded is previously used to superimpose further 2D information to record additional information.
The exemplary structure of the manufacturing apparatus described in the first embodiment is used without any modifications to make the hologram recording medium in the second exemplary construction of the second embodiment. The 3D information is plotted before the 37 * · · Λ -V * · · · shown in FIGS. 29A to 29C.
Monomer Μ is polymerized, wherein the monomer M is polymerized after the 2D information has been recorded as additional information. That is, the images are fixed after the 2D information is recorded on the hologram recording medium 1 on which the 3D information was previously recorded.
In accordance with the second exemplary construction of the second embodiment, 3D information and 2D information may be recorded on a hologram recording medium, the 2D information being viewed from a predetermined viewing direction within a predetermined angular range. ≪ 3rd Third embodiment >
Now, a third embodiment should be described.
In accordance with the third embodiment, a hologram reproducing apparatus is constructed such that a
Object to be considered on one
Viewing table is arranged. The object to be considered is given a predetermined one
Illuminated illumination light from a given direction. The illumination light is designed so that it does not run directly to a viewer. The viewer views the object to be viewed through an optical aperture in a given direction.
Individual pieces of the recorded information can thus be selectively reproduced from a hologram recording medium, whereby the viewer can easily, quickly and reliably view the individual pieces of the recorded information.
[Exemplary Structure of Hologram Rendering Device]
Figs. 12A and 12B and Figs. 13A and 13B show an exemplary structure (a first exemplary construction) of an apparatus for reproducing a hologram recording medium. Fig. 12A is a perspective view showing an exemplary structure of the hologram reproducing apparatus 38. Figs. Fig. 12B is a front view showing the exemplary structure of the hologram reproducing apparatus. Fig. 13A is a plan view showing the exemplary structure of the hologram reproducing apparatus. Fig. 13B shows a section along the axis X-X of Fig. 13A.
In the exemplary structure shown in Figs. 12A and 12B, and Figs. 13A and 13B, the hologram reproducing apparatus 2 is formed substantially box-shaped. The bottom of the hologram reproducing apparatus 2 forms a viewing table 4. A support member 6 constituting the side surfaces and a rear surface is fixed to the viewing table 4. A light blocking member 8 is disposed on the support member 6 and forms an upper surface of the hologram reproducing apparatus 2. A transparent member 10 forms a front surface of the hologram reproducing apparatus 2. The above-described components constitute a housing of the hologram reproducing apparatus, wherein a plurality of Light sources 12L, 12c, 12R, 12E and 12X, 12y, 12w, 12z is arranged in the housing.
In Be table 4, an opening 4 a is provided. The opening 4a is provided so as to be able to arrange a hologram recording medium 1, which is an object to be viewed. Furthermore, a high-frequency pattern 4p different in brightness is provided, which is produced, for example, in a printing operation. The high-frequency pattern 4p is used when an imaging device captures an image of the hologram recording medium 1, as will be described later. The plurality of light sources 12L, 12c, 12R, 12e and 12x, 12Y, 12w, 12z are fixed to the support member 6 so as to emit light in predetermined directions.
The Lichtabsperrelement 8 has a Lichtabsperrteil 8 b, which is formed by a downwardly bent portion of the Lichtabsperrelements 8, which leads to an optical opening OP over the opening 4 a, which is provided in the treatment table 4 Be. The Lichtabsperrteil 8b may alternatively be a device that from 39
Lichtabsperrelement 8 is disconnected. The optical aperture may be formed such that no device is disposed therein, or it may be provided with a transmissive element which is transparent enough so as not to obstruct the viewer from seeing the hologram recording medium 1 incorporated in the opening is arranged. The light shut-off member 8 is provided so as to prevent light emitted from the plurality of light sources from leaking to the viewer through the optical opening OP.
The hologram recording medium 1 is viewed and imaged as follows: the hologram reproducing apparatus 2 is arranged so that the hologram recording medium 1 disposed in the opening 4a is visible, the hologram recording medium 1 being from the eyes of the observer can be seen and imaged through the optical aperture OP. In this example, the hologram recording medium 1 can be viewed and imaged in a direction substantially perpendicular to the surface of the hologram. The hologram recording medium 1 is desirably imaged in the vertical direction within a range of about ± 10 °. The reason for this is that an imager used to capture an image of the hologram is held parallel to the surface thereof over the area to be read, whereby the entire area is reliably focused and no trapezoidal distortions need to be corrected, or other additional operations necessary.
The plurality of light sources 12L, 12c, 12R, 12E and 12x, 12y, 12w, 12z are provided to selectively reproduce plural pieces of information recorded on the hologram recording medium 1. That is, each of the light sources is aligned in a given direction, emitting light that is within a predetermined wavelength band. Each of the light sources may be, for example, a light emitting diode. As shown in Fig. 12B, the light sources 12L, 12c and 12R, which are white light-emitting diodes for lighting purposes, are downward but rightward, straight down, and 40 • ····· v. · * ··, respectively. »* *» · »*» * * * * ¢ 4 »- * but directed to the left but to the left, the light source 12e, which is a red light emitting diode for illuminating an embossed hologram, is also provided. Further, the light sources 12x, 12Y, 12w and 12z are provided, which are white LEDs for illuminating the entire high-frequency pattern 4p.
A mirror 14 is disposed in a lower portion of the transparent member 10 with the reflecting surface of the mirror 14 directed inwardly of the housing. The mirror 14 serves to illuminate the hologram recording medium 1 in a downward but leftward direction in FIG. 13B. That is, among the plurality of light sources, a preferred light source (for example, the center white light emitting diode light source 12c for illumination) is aligned so that the hologram recording medium 1 is illuminated with light emitted from the given light source and reflected by the mirror 14 becomes.
Furthermore, a diffusion light source 16 may be provided which emits light that passes through the transparent element 10 and the Ho logramm recording medium 1 illuminated. The diffusion light source 16 is formed by, for example, light emitting diode light sources 16a and 16b (the light emitting diode light source 16b is not shown), an outer shell 16c, and a diffuser 16d.
It should be noted that the number of light sources, the type of the light sources, their combination and other factors described above are given herein by way of example only, and may be appropriately changed in accordance with the types of information displayed on the Hologram recording medium 1 are recorded. The wavelength band of the light emitted from each of the light sources need not necessarily be in the visible range, but may be within a near infrared range, an infrared range, a near ultraviolet range, or an ultraviolet range. The hologram reproducing apparatus 2 preferably further comprises a switch and a circuit for controlling the video signals. *** ""
To change the light source that illuminates the hologram recording medium 1. Alternatively, a movable mirror may be arranged to reflect the light from any of the light sources so that the direction of illumination can be changed or adjusted. (Viewing a hologram on which 2D information is recorded)
In order to machine read a hologram recording medium 1 on which many pieces of 2D information are recorded, it is conceivable that illumination light sources are provided in a reader, whereby images of the hologram recording medium 1 are captured at predetermined angles. Simply placing light-emitting diode light sources or other suitable light sources in the reader causes the intensity of the diffracted light to degrade disadvantageously in the region that is not at the intersection of the line containing the center of each light source with the imaging device and the hologram recording medium 1 connects, as well as in the vicinity of the point of intersection.
Fig. 14A is a simplified view showing how an image is reproduced when a single light-emitting diode light source 20 illuminates the hologram recording medium 1. Figs. Fig. 14B is a simplified view showing a reproduced image which is seen when reproducing character information recorded on the hologram recording medium 1 by illuminating the hologram recording medium 1 at a predetermined angle , Fig. 14C is a simplified view showing a reproduced image which is seen when a two-dimensional bar code recorded on the hologram recording medium 1 is reproduced by the hologram recording medium 1 at another predetermined angle is looked at. This also applies to Figs. 15B and 15C to Figs. 18B and 18C to be used in the following description. When only a limited range of 2D information recorded on the hologram recording medium 1 is brightly reproduced, as shown in Figs. 14B and 14C, it is difficult to read out the entire recorded information in a single operation. (Illumination source)
A preferred example of the light source for illuminating the hologram recording medium 1 will now be described.
Fig. 15A shows an example of the light source for illuminating the hologram recording medium 1. In Fig. 15A, a light source 22, the hologram recording medium 1, and the imaging device 71 are shown as viewed from the side. This also applies to Figs. 16A to 18A, which will be used in the following description. In the example shown in FIG. 15A, a diffusion element 32 is disposed at a position somewhere along a straight line connecting the light source 22 with the hologram recording medium 1. The diffusion element 32 consists for example of a diffuser.
In Fig. 15A, the reference V denotes the length of the area where the 2D information is recorded. The reference character L denotes the distance between the diffusion member 32 and the hologram recording medium 1. The reference character α denotes the angle between a normal to the hologram and a straight line connecting the root of a normal to the hologram with the light source. In this case, the length Vd of the diffusion element 32 is preferably at least 75% of Vxcosa. Further, preferably, the following relationship is satisfied: V ^ 2Lxtan, where ± β is a longitudinal diffusion angle provided by the diffusion element 32. That is, the diffusion area of the illumination light in the longitudinal direction is set to be longer than or equal to the length of the area where the 2D information is recorded. The reason why Vxcosa is multiplied by 75% is that an optical experiment has shown that the 2D information is successfully read out when the length Vd is at least 0.75Vxcosa, although a desired 43
Value of it at least Vxcosa is.
In this way, the entire recorded 2D information is clearly reproduced and the viewer can see the thus reproduced image shown in Figs. 15B and 15C.
Fig. 16A shows an example of the light source for illuminating the hologram recording medium 1. In the example shown in Fig. ISA, a collimating lens 34 is disposed at a position anywhere along the connecting line of a light source 24 with the hologram recording medium 1.
In Fig. ISA, reference character r denotes the radius of a circle C which encloses the area in which the 2D information shown in Figs. 16B and 16C is plotted. The reference character α denotes the angle between a normal to the hologram and a straight line connecting the base point of the normal to the hologram with the light source. In this case, the opening diameter of the collimating lens 34 is preferably at least 75% of 2rxcosa. The reason why 2rxcosa is multiplied by 75% is that an optical experiment has shown that the 2D information is read out successfully if the aperture diameter is at least 0.75x2rxcosa, although a desirable value thereof is at least equal to 2rxcosa.
In this way, the entire recorded 2D information is clearly reproduced, and the viewer can see the thus reproduced image shown in Figs. 16B and 16C.
Fig. 17A shows an example of the light source for illuminating the hologram recording medium 1. In the example shown in Fig. 17A, a reflection plate 36 is disposed at a position somewhere along the extension of a straight line connecting the light sources 24a and 24b with the hologram. On the recording medium 1 on the side of the light sources 24a and 24b connects, which lies on the other side as the hologram recording medium 1. The reflection plate 36 may, for example, be made up of a concave one-by-one concurrent V * I * i * 44. * * * * * * * * * * * *
Mirrors are, but are not limited to, any device that has a certain reflectivity can be used.
The surface of the reflection plate does not have to be smooth. The shape of the concave cross section that runs along a surface including a straight line connecting the reflection plate 36 to the hologram recording medium 1 is not limited to the shape of an arc, but may be parabolic, elliptical, free curved, polygonal , a part of any of the forms described above, or a combination thereof. The reflection plate 36 may be a one-piece element or may be formed of a plurality of elements.
In Fig. 17A, the reference character r denotes the radius of a circle C enclosing the area in which the 2D information shown in Figs. 17B and 17C is plotted. The reference character α denotes the angle between a normal to the hologram and a straight line connecting the base of the normal to the hologram with the light sources. In this case, the radius R of a circle enclosing the outline of the cross-sectional shape of the reflection plate 36 on the side on which the reflection plate 36 opens to the hologram recording medium 1 in the direction perpendicular to the straight line communicating with the light sources 24a and 24b the hologram recording medium 1, preferably at least 75% of rxcoso ;. The reason why rxcosa is multiplied by 75% is that an optical experiment has shown that the 2D information is successfully read out when the radius R is at least 0.75rxcosa, although a desired value thereof is at least equal to rxcosa ,
In this way, the entire recorded 2D information is clearly reproduced and the viewer can see the reproduced image shown in Figs. 17B and 17C.
Fig. 18A shows an example of the light source for illuminating the hologram recording medium 1. In Fig. 18A, "* * **" * *. * * * * 4 * * *. In the example shown in FIG. 45, the light source for illuminating the hologram recording medium 1 is made up of a group of .mu.m.sup.-1
Light sources 26, which is formed by a plurality of light sources.
In Fig. 18A, reference character r denotes the radius of a circle enclosing the area in which the information shown in Figs. 18B and 18C is plotted. The reference character α denotes the angle between a normal to the hologram and a straight line connecting the root of the normal to the hologram with the group of light sources. In this case, the group of light sources 26 is preferably arranged in a region formed by a circle having a radius rxcosa in a section in the direction perpendicular to a straight line connecting the group of light sources to the hologram recording medium 1 has.
In this way, the entire recorded 2D information is clearly reproduced and the viewer can view the thus reproduced image shown in Figs. 18B and 18C.
In the cases shown in Figs. 16A to 16C to 18A to 18C, it is preferable that further
Light diffusion element between the light source (the light sources) and the hologram recording medium 1 is provided to increase the uniformity of the light with which the hologram recording medium 1 is illuminated. (Detecting Holographic 2D Information Using Imaging Device)
On the hologram recording medium 1, many pieces of 2D information are recorded, which can be optionally reproduced simply by displaying the hologram recording medium 1 with light of a variety of types
Lighting angles is illuminated. The recording of individual ID information as 2D information on the hologram recording medium 1 enables the
Hologram recording medium 1 or an object to which the hologram recording medium 1 is attached, 46 • · «« ι; 1 can be identified as to whether they are real or not, when the hologram reproducing apparatus 2 is thus arranged and a light source among a plurality of light sources is turned on to illuminate the hologram recording medium 1. It is preferred that the identification of the authenticity is carried out not only by optical control but also by machine read-out.
Figs. 19A and 19B are simplified views showing an example in which a hologram recording medium on which many pieces of 2D information are recorded is attached to a product package. Fig. 19B shows a section along the axis Y-Y of Fig. 19A.
In the example shown in Figs. 19A and 19B, a hologram recording medium 1 on which many pieces of 2D information are recorded is attached to a part of a Brewster package 42 containing batteries. For example, a one-dimensional barcode and a character information are recorded as 2D information. When the hologram recording medium 1 is a translucent hologram, information printed on the surface on which the hologram recording medium 1 is mounted can be recognized by the hologram recording medium 1. In this case, the 2D information recorded on the hologram recording medium 1 does not prevent the printed information from being seen.
The hologram recording medium 1 is placed in the opening 4a in the hologram reproducing apparatus 2, and the recorded 2D information can be seen through the optical opening OP, as shown in Fig. 19B. Since the hologram reproducing apparatus 2 allows a transparent cover 42cl of the Brewster package 42 to be placed on the hologram reproducing apparatus 2, the hologram recording medium 1 and the hologram reproducing apparatus 2 can be used while the product is in the Brewster format. Packaging is included.
Figs. 20A and 20B are simplified views showing an example of how to read out individual ID information formed as a bar code on a hologram recording medium was recorded.
In the example shown in FIG. 20A, a holder for a diffusion light source 16att, which is combined, for example, with a diffuser and a light emitting diode, is attached to a bar code reader 74, the light emitting diode being turned on upon actuation of the bar code reader 74. When a read-out switch on the barcode reader 74 is placed in an ON position, the LED is turned on, turning off the LED when the 2D information has been completely read out. In this process of reproducing the 2D information, it is necessary that the 2D information be reliably illuminated and read out in a predetermined direction.
In the example shown in FIG. 2OB, the 2D information is read out by using the holder as well as other components to fix the bar code reader 74 to the hologram playback device 2. The 2D information can be read out reliably and quickly when the above-described construction is used. The use of the hologram reproducing apparatus 2 is also advantageous in that not only the image sab st and a target can be accurately determined, but also unnecessary lights are blocked. The use of the hologram reproducing apparatus therefore has an advantage of reducing the incidence of read-out errors originating from an external environment. Further, since many parts of 2D information can be changed from one part to another and read out quickly, authentication of authenticity based on a combination of the many pieces of 2D information can be reliably performed. Furthermore, the information thus read out can be transmitted and received, for example, via a wireless connection, an optical connection, a biocommunication to and from an information processing device, a database and other devices. 48 • * * * * * *% *** * * .ί * · ** · «t I« • ι «* v« ·. »···· ** · I *« ···· * »· * *. · · I- .. i kt · e * Φ
Figs. 21A and 21B are simplified views showing an example in which a digital camera 71dc captures an image of a hologram recording medium 1 on which many pieces of 2D information are recorded. Fig. 21B shows the section along the axis X-X of Fig. 21A.
In the example shown in Fig. 21A, character information is reproduced as 2D information. Also in this case, a holder or any other component is preferably used to fix the digital camera 71dc to the hologram reproducing apparatus 2. Alternatively, an imaging device formed of, for example, a universal digital camera, a USB (Universal Serial Bus) camera, and a bar code reader may be included in the hologram reproducing apparatus 2 itself. In another alternative, an imaging device may be included in the hologram display device 2 itself, which is formed by, for example, a CCD (Charge Coupled Device) sensor and a CMOS device. (High frequency patterns)
If a holographically recorded 2D information is read out from a digital camera, with only one hologram illuminated, this can result in too high a contrast ratio as well as an auto focus and exposure not working in some cases.
The reason for this is that a typical digital camera uses an algorithm that judges a point where the contrast ratio is maximized in a focused point, the distance to which is a focusing
Picture distance can be. In other words: the
Focusing on an autofocus operation involves one light and one dark, high-frequency part. For this purpose, the observation table 4 in the hologram reproduction apparatus 2 is provided with the high-frequency pattern 4p different in brightness. In this case, the 2D information to be rendered is rated to be focused when the 49 * t * * I * *. ; ι a;. ·; * • * ft * » J '* • «« * * S- ft 4 »« • »-14» 4 • · · * * «·» * ft. ♦ -. t i ft
High-frequency pattern 4p is evaluated so that it is focused in the auto-focus operation. The high-frequency pattern 4p may also be provided only around the opening 4a.
Figs. 22A to 22D show examples of the high-frequency pattern. The patterns shown in Figs. 22A to 22D are shown here by way of example only, with any other possible patterns, a combination of parts of those patterns shown in Figs. 22A to 22D, or an arbitrary pattern being used, the black one and has white edges. An arbitrary pattern that can be used is not necessarily a combination of black and white, but may have other suitable color combinations. An increase in the proportion of very light parts is preferred because the amount of light incident on the imaging device is increased.
The difference in brightness between a very bright part and a less bright part is basically due to the spectroscopic feature of the light source multiplied by the spectroscopic reflection of the high frequency pattern. In practice, the difference in brightness depends on the spectroscopic feature of the sensor and a threshold in a method of contrast detection, where it can not be easily determined, but when a pattern is used, the difference in luminance ratio of at least 20 %, which is obtained with a luminance measurement, which is set in Figs. 26A and 2 6B (measuring device: luminance meter and
Colorimeter (Konica-Minolta CS-200), illumination light source: oblique illumination at 45 ° with a halogen light source (Y: 96.0, x: 0.4508, y: 0.4075 in an XY chromaticity diagram) and standardized white plate: ( Konica-Minolta CSA20)}, it has been shown that a high-frequency pattern can easily be focused in a statistically-secure manner (in accordance with results obtained in experiments involving at least 20 types of commercially available digital cameras, barcode readers and used by other devices).
The parts with high brightness are
* * * * v * «tM Vt (« I ·· * · * · · · * I * · I ιI «4 I f • * * ·« f ft II »1 I ·« (*> 1 ι For example, the high frequency pattern 4p may be formed by a glossy or fluorescent plate on which a black pattern is imprinted.
On the other hand, the high frequency pattern 4p may be on
Be background light based device. Fig. 23 shows a simplified section through an edge-illuminating backlight 76. As shown in Fig. 23, light Lf emitted from a cold cathode tube 76cct is reflected several times by a light guide plate 761gp, with the light reflected from reflection points 76rd being the light reflected from the light source are provided along a main surface of the light guide plate 761gp, exit from the light guide plate 761gp to form regions of high brightness. Alternatively, the
Background light is an overhead background light provided with Lichtabsperrbereichen. When a backlight is used to form a high-frequency pattern, it is preferable that the difference in height between the surface of the backlight and the surface of the hologram be small, so that both can be reliably focused. Specifically, the thickness T of the light guide plate 761gp is preferably 3 mm or smaller.
Alternatively, the hologram recording medium 1 and the high-frequency pattern 4p may be illuminated from a position enabling the intensity of the diffracted light of a reproduced image to be any portion of the 2D information recorded on the hologram recording medium 1 20% of a maximum value or less, preferably 10% or less. The white light emitting diode light sources 12x, 12Y, 12w and 12z are arranged to provide this illumination. When a white light source is used, it has been found that when a white light source having a color temperature in the range of 3,000 to 9,500 K is used in a digital camera or in a video camera using an automatic light source
White balance, a satisfactory white balance can be achieved.
A light source for illuminating a hologram preferably emits light containing a wavelength fraction, which corresponds to a color required to reproduce the recorded information. It has been found that a hologram to be reproduced with green light can be easily focused if a white light-emitting diode is used instead of a green light-emitting diode.
If a green Lippmann-Ho logramm is the object to be identified, a red light emitting diode and a mode of operation may be provided in which the hologram is viewed, with only the turning on of the red
LED is effective to obtain a confirmation of the authenticity between the green Lippmann hologram and an embossed hologram, which were created so that they are similar to each other. The red light emitting diode light source 12E for illuminating an embossed hologram is provided for this authentication of authenticity. As a light source for illuminating an embossed hologram, a
Laser light source and a red light emitting diode light source can be used. In this case, the light for illuminating the hologram recording medium 1 desirably has a peak intensity within a wavelength band which causes the intensity of the diffracted light of a reproduced image to be preferably 20% of a maximum value or less, more preferably 10% or less.
Second Exemplified Construction of Third Embodiment
Figs. 24A and 24B and Figs. 2A and 2B show a second exemplary construction of the apparatus for reproducing a hologram recording medium. Fig. 24A is a perspective view showing the second exemplary construction of the hologram reproducing apparatus. Fig. 24B is a front view showing the second exemplary construction of the hologram reproducing apparatus. Fig. 25A is a plan view showing the second exemplary construction of the hologram reproducing apparatus. Fig. 25B shows a section along the axis X-X of Fig. 25A.
The second exemplary structure differs from the first one. 52 * * * * * * * * * * * * * * «« I * * * * * * "4 9" * "II" * * · «« "* ir * Exemplary structure in that the viewing table 4 is not disposed in the housing of a hologram reproducing apparatus 202, but protrudes from the front side. As a result, no mirror 14 is provided, wherein the part above the opening 4a is open. In this example, the diffusion light source 16 is arranged so that the light emitted from it first passes through the transparent member 10 and then illuminates a hologram recording medium 1, as in the first exemplary construction.
In order to make the hologram reproducing apparatus 202 smaller, the viewing table may be formed so as to be retractable into the housing, or a hinge or any other suitable member may be provided between the viewing table 4 and the transparent member 10, that the viewing table 4 can be raised upwards.
In accordance with the second exemplary construction of the third embodiment, individual pieces of information recorded on the hologram recording medium can not only be selectively reproduced but also viewed easily, quickly and reliably, as in the first exemplary construction of the third embodiment is. ≪ 4th Variants >
Hitherto, preferred embodiments have been described, but preferred specific examples are not limited to the above description. For example, the 2D information may further include a serial number, a manufacturer, a lot number, a producer, a one-dimensional bar code, a two-dimensional bar code, and other identification information, and may be recorded as individual ID information. Furthermore, a fingerprint or other biometric information can be recorded. The recording of an individual ID information in the form of a 2D information as well as a machine readout of the recorded information can be a radio frequency identification (Radio
Frequency Identification RFID) for authenticity confirmation replace or used in combination. The hologram recording medium described above may also be used as an information storage such as a non-volatile memory.
The number of pieces of recorded image information is not limited to two or three parts, but may be larger. The direction in which the information reproduced from a hologram recording medium is changed is not limited to the horizontal direction of the recording surface, but may be a vertical direction, a diagonal direction or any other direction.
The hologram recording medium described above may be attached to a product package, a contactless IC card, an ID card, a black card, a credit card, an employee identification card, a student identification card, a season pass, a driver's license, a passport, a visa , be attached to securities, a savings account, a stamp, a stamp, a mobile phone, a coin, a lottery ticket as well as to a variety of other items. In the above description, a liquid crystal panel is used as a spatial light modulator, but the spatial light modulator is not limited thereto. The diffuser 25 (or the diffusers 25 a and 25 b) may further be disposed in the vicinity of the hologram recording medium 1. The recording of the image information has been described in the context of the case where the spatial light modulator has been projected in a 1: 1 projection scheme, but the spatial light modulator can also be projected in an enlarged or reduced projection scheme. The sheet-like hologram recording medium described in the second embodiment can also be used as the hologram recording medium in the other embodiments.
The light source for illuminating the hologram is not possible. * * * * * * * * * * * T »
· ** ·· * «« I
Recording medium 1 is not limited to a light emitting diode, but may be a xenon lamp, a halogen lamp, a fluorescent lamp or an external light that is passed through an opening or a light guide.
The present disclosure includes a subject matter relating to the subject matter disclosed in Japanese Patent Application No. 2010-149572 filed in the Japanese Patent Office on June 30, 2010, the entire contents of which are hereby incorporated by reference. It will be apparent to those skilled in the art that various changes, combinations, subcombinations, and variations depending on structural requirements and other factors may be made if they come within the scope of the appended claims or their equivalents.

权利要求:
Claims (24)
[1]
φ *

* «Φ ** ··· * ··························································································································································································································································· when substantially collimated light falls along a first direction on the hologram recording medium, a first image is reproduced with the intensity of light diffracted in the hologram recording medium maximized in a given direction when substantially collimated Light is incident on the hologram recording medium along a second direction, a second image is reproduced with the intensity of light diffracted in the hologram recording medium maximized in the predetermined direction, the total width of a reproduction angle being half maximum of at least one of the intensities of the diffracted light of the first and second images is equal to or smaller than 8 °.
[2]
The hologram recording medium according to claim 1, wherein the directions in which the intensities of the diffracted light of the first and second images are maximized are in the vicinity of the direction of a normal to an area on which the first and second images are recorded.
[3]
The hologram recording medium according to claim 2, wherein the angle between the first direction and the normal is about 45 °, and the angle between the second direction and the normal is at least 10 °, but less than or equal to 35 °.
[4]
The hologram recording medium according to claim 2, wherein the angle between the first direction and the normal is about 45 °, and the angle between the second direction and the normal is at least 55 ° but less than or equal to 80 °.
[5]
5. hologram recording medium according to claim 2, 56 • * * * * * e * * * * * * * * * * * * * * * * * * * * * * * »* * * * * t 4 * «. The angle between the first direction and the normal is about 45 °, and the first and the second direction are symmetrical to the normal.
[6]
The hologram recording medium according to claim 1, wherein both the intensity of the diffracted light of the first and second images in the vicinity of the direction of the normal is at least five times larger than the intensity of the other diffracted light.
[7]
A hologram recording medium according to claim 1, wherein an image diffracting light so that the entire width of the reproducing element is equal to 8 ° or smaller at the maximum of the intensity of the diffracted light is 8 ° or less as the character, number, symbol, figure, pattern , one-dimensional barcode, two-dimensional barcode, or a combination thereof.
[8]
8. A method of making a hologram recording medium, the method comprising: modulating laser beams in spatial light modulators into laser beams, each of which contains additional information; and illuminating a hologram recording medium via optical focusing systems with the modulated laser beams together with a reference light, wherein at least one of the optical focusing systems provides a diffusion angle having an absolute value of 7 ° or smaller.
[9]
A hologram reproducing apparatus comprising: a viewing table having an opening; a holding member fixed to at least a part of the viewing table; to a light shut-off member having a Lichtabsperrteil and is fixed to the holding member on a side which is closer to a viewer as a viewing table; and # I · it * 4 * 4 «fti. * ·« «4 ··« 4 «ft • 4 · · ·« 4 * 4 «« • ·· * · · * · ft • I · 4 · · · A plurality of light sources mounted on the support member, the viewing table being constructed so that a hologram can be arranged to be viewed when; disposed in the opening, each of the plurality of light sources illuminates the hologram in a predetermined direction, a portion of the light shutoff element corresponding to a portion above at least the opening is an optical opening, and the light shutoff portion prevents illumination light from each of the light sources directly through the optical opening.
[10]
10. The hologram reproducing apparatus according to claim 9, wherein the plurality of light sources illuminate the hologram in different directions, and the hologram reproducing apparatus further comprises a switch with which the plurality of light sources can be individually turned on and off.
[11]
The hologram reproducing apparatus according to claim 9, wherein a high-frequency pattern different in brightness is formed on at least a part of the viewing table.
[12]
12. A hologram reproducing apparatus according to claim 11, wherein the high frequency pattern is formed on a lighting device having a light guide plate, a light source disposed at one end of the light guide plate, and reflecting elements disposed at least on a part of the light guide plate.
[13]
The hologram reproducing apparatus according to claim 11, wherein the high frequency pattern is partially made of a glossy or fluorescent material.
[14]
The hologram reproducing apparatus according to claim 9, wherein the apparatus comprises an imaging device. 58 "*" * "* * ··· *" * · * * »» · «* *» t < «4 * *
[15]
15. A hologram reproducing apparatus according to claim 14, wherein the apparatus further comprises an adjusting member that can adjust and fix the imaging device.
[16]
The hologram reproducing apparatus according to claim 9, wherein the apparatus further comprises a light diffusion member disposed between at least one of the light sources and the hologram, the length of the diffusion member being at least 75% of Vxcoso; and V ^ 2Lxtanß is satisfied (where V is the length of a recording area of the hologram, with α the angle between a normal to the hologram and a straight line connecting the base of the normal to the hologram with the light source, with the distance between the diffusion element and the hologram and with ± ß denotes a Längsdif fusion angle, which is supplied from the diffusion element).
[17]
The hologram reproducing apparatus according to claim 9, wherein the apparatus further comprises a collimating lens disposed between at least one of the light sources and the hologram, wherein the aperture diameter of the collimating lens is at least 75% of 2 rxcosa (where r is the radius of a circle, encloses a recording area of the hologram, and α is the angle between a normal to the hologram and a straight line connecting the base point of the normal to the hologram with the light source).
[18]
The hologram reproducing apparatus according to claim 9, wherein the apparatus further comprises a reflection plate having a radius of at least 75% of rxcosa (where r is the radius of a circle enclosing a recording area of the hologram and α is the angle between a hologram Normal to the hologram and a straight line connecting the foot of the normal with the light sources). 59 4 4 59 4 4 • l • · * • · • ·
[19]
19. A hologram reproducing apparatus according to claim 9, wherein a group of light sources formed by at least two of the light sources is arranged in a region formed by a circle having a radius rxcosa, where r is the radius of a circle is designated, which encloses a recording area of the hologram.
[20]
20. The hologram reproducing apparatus according to claim 17, wherein the apparatus further comprises a light diffuser disposed between at least one of the light sources and the hologram.
[21]
The hologram reproducing apparatus according to claim 9, wherein the apparatus further comprises a light source illuminating the viewing table in a direction causing the intensity of the light diffracted in an image recorded on the hologram to be smaller or smaller is equal to one tenth of a maximum value of the intensity of the diffracted light.
[22]
The hologram reproducing apparatus according to claim 21, wherein the light source illuminating the viewing table is a white light source having a color temperature ranging from 3,000 to 9,500K.
[23]
The hologram reproducing apparatus according to claim 9, wherein the apparatus further comprises a light emitting diode or a laser light source having a peak intensity within a wavelength band causing the intensity of light diffracted in an image recorded in the hologram to be increased. is less than or equal to one tenth of a maximum value of the intensity of the diffracted light.
[24]
24. A hologram reproduction method, the method comprising: (setting the direction of a normal to a hologram on which a plurality of pieces of image information are recorded 9 f 1 t • t eo, a direction of an illuminating light illuminating the hologram, and a hologram Direction from which the hologram is viewed); Selecting one of image information from the many pieces of image information recorded on the hologram by keeping either of the two directions fixed and changing the remaining direction; and viewing the selected image information.

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法律状态:
2017-02-15| MM01| Lapse because of not paying annual fees|Effective date: 20160621 |

优先权:

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JP2010149572A|JP2012013902A|2010-06-30|2010-06-30|Hologram recording medium, manufacturing method thereof, hologram reproducing apparatus, and hologram reproducing method|

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