The current application is the PCT/JP2013/071827, filed on Aug. 12, 2013, entering U.S. National Stage application.
The PCT/JP2013/071827 claims priorities to Japan patent application No. 2013-000249 filed on Jan. 4, 2013, and Japan patent application No. 2012-180691 filed on Aug. 17, 2012.
The present invention relates to an illuminating device and a medium to be illuminated that are a penlight/flashlight for lighting in a dark place and for presenting dramatic effects, with a functionality for effective viewing of a hologram or a holographic stereogram.
Reproduction of a three-dimensional image (holographic image) is made possible with a hologram by its illumination by a reproducing light. Whereas in some cases coherent light such as laser light is required, in the case of the reproduction of a hologram such as a rainbow hologram or a Lippmann hologram incoherent white light such as a halogen lamp or natural light can be used.
Such holograms that allow the use of white light sources as the reproducing light have been widely utilized for purposes such as prevention of forgery of credit cards. Various holographic display devices are also being utilized as devices such as for displaying holographic images for viewing enjoyment.
When a hologram is illuminated by reproducing light, the optical wavefronts of the light from the recorded object during the recording are reproduced, and these wavefronts are viewed as a holographic image by the viewer. What is referred to as the holographic stereogram is another kind of hologram. A holographic stereogram is produced, using as the original images a large number of images obtained by capturing images of the subject sequentially from different viewpoints, by recording on a single sheet of hologram recording medium consecutive exposures of element holograms in the form of strips or dots.
For example, a holographic stereogram that has parallax information only in the horizontal direction is produced by sequentially displaying on the display of a holographic stereogram printing system incorporating a prescribed optical system a plurality of original images that are obtained by sequential image capture of the subject 100 from different horizontal viewpoints and illuminating the displayed images with laser light to execute consecutive exposures to record on a hologram recording medium, as element holograms, the interference fringes generated by interference between the object light, which is modulated as an image, and the reference light.
Because the image information obtained by successive capture of images from different horizontal viewpoints are consecutively recorded in the horizontal direction as strips of element holograms, the collection of image information recorded as a certain part of each element hologram is perceived as a two-dimensional image when seen by the viewer with one eye from a particular position, and the collection of image information recorded as a different part of each element hologram is perceived as a different two-dimensional image when seen by one eye from a different position. Therefore, when the viewer sees a holographic stereogram with both eyes the exposed image record is perceived as a three-dimensional image due to the parallax between the left and right eyes.
In order to improve the legibility of the holographic image with satisfactory reproduction of holograms such as the holographic stereogram described in the preceding paragraphs, the angle of divergence of the illuminating light from the light source that is used as the reproducing light must resemble that of the reference light upon recording the hologram, or it must be parallel light. Therefore, in the reproduction of a hologram the legibility and image quality of the holographic image that is viewed depends on the spatial relationship of the positions of the hologram, the light source and the viewer, as well as on their physical forms.
Therefore, especially in displaying a hologram for the purpose of viewing enjoyment, it is necessary to enable satisfactory reproduction of the holographic image by constraining the relative positions of the hologram, light source and viewer.
As described in Patent Document 1 in the following list, for example, various devices for display of holograms have been proposed that comprise a hologram and a light source for illuminating the hologram with reproducing light.
There are also various proposals of penlights for use in such events as concerts.
There are also various proposals of flashlight functionalities that can be used in such scenes as disasters.
These previous holographic display devices required much effort to transport and carry because of their large sizes. The conventional holographic display device described in Patent Document 1 is made to be a construction with great volume and weight due to the complexity and elaborateness of the light source for illuminating the hologram with reproducing light and of the optical system for the improvement of the legibility of the holographic image by constraining the relative positions of the hologram, the light source and the viewer.
Although the portability of the pen-type viewer described in Patent Document 2 is good, it is strictly a device used for the purpose of illuminating a hologram, and has the disadvantage of the extensive handling that is required in setting up for viewing.
Further, the hologram wrapper described in Patent Document 3 is also strictly a device used for the purpose of illuminating a hologram. Although it enables both the holding of the hologram and the light source in optimal relative positions upon viewing and the elimination of the risk of breakage and damage to the surface of the hologram during transportation and carriage, it can hardly be used to function for other purposes such as lighting a dark place or enhancing decorativeness. Other proposals have also been made to illuminate a hologram from a predetermined angle in addition to improving the portability, but none of these provided any decorative effect, to the hologram or when the hologram is not being viewed, through the combination of the light source and an optical diffuser element.
Further, although many types of penlight have been proposed for use in such events as concerts, such as a multicolor penlight of a type described in Patent Document 4 and flashlights and compact penlights for the purpose of use in disasters and in searching for a keyhole in a dark place, they are difficult to use unless the user is trained because of the required understanding of fundamental knowledge about the direction from which the light source must illuminate the hologram.
Therefore, the purpose of this invention is to provide the functionality of holographic viewing, capable of reproducing a good holographic image, to an article that is highly portable and that can be used in the fashion of a flashlight or a penlight or as a decorative light that gives a dramatic presentation effect on people.
In order to realize a solution to the issues described in the preceding paragraphs, this invention provides an illuminating device with the features of comprising a unit for holding a hologram or a holographic stereogram, a light source, a battery and an optical diffuser, of having a member acting as an optical diffuser of the light from the light source, and of providing the capability to attach such hologram or holographic stereogram in a condition such that no member other than those which are optically nearly transparent is placed within the optical path from the light source to the image region of such hologram or holographic stereogram or within the zone of directions from at least 20 degrees above to 20 degrees below, and from 45 degrees to the left to 45 degrees to the right, with respect to the normal to the center of the area of the hologram on the side of the viewer.
In an example of a preferred embodiment, there is a mechanism to switch between a first configuration in which the light from the light source is led into the light-guiding diffuser and a second configuration in which it is made to illuminate such a hologram support unit from a predetermined angle, by joining the carrier for the light source and the light-guiding diffuser, both described in the preceding paragraphs, by means of a movable element.
This invention enables both the functionalities of use as a flashlight or penlight in disasters and emergencies and of use for decorative/dramatic presentation effects in concerts and events, as well as ready placement and maintenance of the relative positions of the hologram and light source in an optimal relationship.
In addition, it enables, by simultaneous or sequential illumination of the optical diffuser element that is placed in the illuminating device, the expression of decorativeness that was not possible by the hologram alone.
Hereinafter, the best modes (hereinafter, referred to as “embodiments”) for implementing the invention will be described. Descriptions will be given in the following order.
1. Recording of an element hologram on a hologram recording medium 2. First Embodiment 3. Second Embodiment 4. Third Embodiment 5. Fourth Embodiment 6. Fifth Embodiment 7. Sixth Embodiment 8. Seventh Embodiment 9. Eighth Embodiment 10. Ninth Embodiment 11. Tenth Embodiment 12. Eleventh Embodiment 13. Twelfth Embodiment 14. Thirteenth Embodiment 15. Fourteenth Embodiment 16. Modified Embodiments
Those described below are preferred embodiments of the invention and are thus limited in terms of technical preference. The scope of the invention, however, is not limited to those embodiments unless otherwise indicated.
Hereinafter, the best modes (hereinafter, referred to as “embodiments”) for implementing the invention will be described, with reference to figures. This invention is applied in attaching a hologram or a holographic stereogram to a wrapper or a display device.
Thus, before describing the wrapper or display device in which this invention is applied, the holographic stereogram is specifically described in the following paragraphs as an example of the hologram or holographic stereogram that is mounted on such wrapper or display device.
First, the principle of the exposure to record an element hologram on a hologram recording medium is described.
The holographic recording medium 3 is composed as a film-coated recording medium, as shown in
As the polymerization of the photopolymerizable photopolymer proceeds, migration of the surrounding monomers M results in variations of their concentration which produces modulations of the refractive index between the exposed and unexposed parts. Then, as illustrated in
In the hologram recording material 3, exposure and recording of interference fringes produced by interference between the reference light and the object light are made as variations of the refractive index by the changes produced in the refractive index of the photopolymerizable photopolymer constituting the photopolymer layer 5 according to the irradiation by laser light LA.
It is not necessary for the hologram recording medium 3 to be subject to a dedicated development process after recording by exposure since it is formed as a film-coated recording medium. Accordingly, the need for the holographic stereogram printing system to have a construction for a development process is obviated by the use of such hologram recording medium 3, which enables simplification of the configuration of the apparatus and rapid production of a holographic stereogram.
In the following, a description is given of the holographic stereogram printing system used for the production of a holographic stereogram using the hologram recording medium 3 described in the preceding paragraphs.
The following description is for the case of the production of a holographic stereogram with horizontal parallax information embedded by exposure and recording of a plurality of strips of element holograms on a single hologram recording medium 3. The holographic stereogram may of course, as an example, have parallax information in both horizontal and vertical directions embedded by exposure and recording of a plurality of element holograms in the form of dots.
The holographic stereogram printing system 10, as shown in
The data processing module 11 comprises at least an image processing computer 14 and a storage device 15 and, for example, generates a parallax image data sequence D3 based on the captured image data D1 incorporating parallax information supplied from a parallax image sequence capturing device 1 by, for example, a multi-view camera or a translating camera, or on image data such as computed image data D2 that incorporate parallax information and that is generated by an image data generating computer 2. The captured image data D1 are a set of a plurality of image data acquired by, for example, simultaneous capture with a multi-view camera or sequential capture with a translating camera, and parallax information is incorporated among individual image data that constitute the captured image data D1. The computed image data D2 are a set of a plurality of image data generated, for example, as CAD (Computer Aided Design) or CG (Computer Graphics) data, and parallax information is incorporated among individual image data that constitute the computed image data D2.
The image data processing module 11 performs prescribed image processing for the holographic stereogram on the parallax image data sequence D3 with an image processing computer 14, based on these captured image data D1 and/or computed image data D2, to generate the hologram image data D4. The hologram image data D4 are temporarily stored in, for example, a storage device 15 such as a memory or hard disk. As described in the following paragraphs, in the exposure and recording of element hologram images on the hologram recording medium 3, the image data of the element holograms are read out from the stored hologram image data D4 sequentially for the data of an individual image at a time, and these element hologram image data D5 are supplied to the control computer 12.
The control computer 12 controls the holographic stereogram printing module 13 to sequentially expose and record element display images, based on the element hologram image data D5 supplied by the image data processing module, as strips of element holograms on the hologram recording medium 3 placed in a part of the holographic stereogram printing module 13. In this function, the control computer 12 controls the operation of each mechanism of the holographic stereogram printing module 13, as described in the following paragraphs.
In the structure of the holographic stereogram printing module 13, each component of the optical system is installed and supported on a supporting plate (optical table) that is not shown in the figure, and this supporting plate is supported by the main frame of the apparatus by means of such components as dampers that are not shown in the figure. The optical system of the holographic stereogram printing module 13 for holographic stereogram printing includes an incident optical system, an object optical system and a reference optical system. The holographic stereogram printing system 10 has a structure in which at least the optical system is shielded from light because of the use of the hologram recording medium 3 which is a photosensitive material.
As illustrated in
The laser light source 21 is composed of a laser device that emits laser light L1 of a single wavelength with good coherence, such as a semiconductor-laser pumped YAG laser device, a water-cooled argon-ion laser device or a water-cooled krypton laser device. The shutter mechanism 22 is opened and closed by the control signal C1 output from the control computer 12 in alignment with the timing of the output of the element hologram image data D5 and introduces the laser light L1 into the optical system of the next stage. Alternatively, it blocks the introduction of the laser light L1 into the optical system of the next stage.
A half mirror 23 splits the incident laser light L1 into the transmitted light and the reflected light. Whereas the transmitted part of the laser light L1 is used as the object light L2 which has been described, the reflected part is used as the reference light L3 These object light L2 and reference light L3 are, respectively, introduced into the object optical system and the reference optical system that constitute the next stage.
Such components as mirrors, although they are not shown in the figure, may be placed in the incident optical system for a purpose such as appropriately altering the direction of travel of the laser light L1 in order to match the optical path lengths of the object light L2 and the reference light L3. In addition, the shutter mechanism 22 may be, for example, constituted to drive a shutter blade mechanically or to be an electronic shutter using an acousto-optic modulator; AOM. That is, the shutter mechanism 22 may be any device that can be controlled to be open or closed to block or transmit the laser light L1.
As the object optical system, the holographic stereogram printing module 13 comprises, as shown in
The mirror 24 reflects the object light L2 that is transmitted through the half mirror 23. The object light L2 reflected by this mirror 24 is incident on the spatial filter 25. The spatial filter 25 is formed, for example, by combining a convex lens with a pinhole, and isotropically expands the object light L2 reflected by the mirror 24 to match the width of the display surface of the transmissive liquid crystal display to be described in the following.
The collimator lens 26 converts the object light L2 expanded by the spatial filter 25 into a parallel beam and guides it onto the transmissive liquid crystal display.
The projection lens 27 makes the object light L2 slightly divergent and projects it onto a cylindrical lens 28. By the slight diverging effect on the object light L2 this projection lens 27 contributes to the improvement of the image quality of the holographic stereogram that is produced.
The object light L2 that is converted into a parallel beam is condensed in the horizontal direction by the cylindrical lens 28.
The mask 29 has a thin rectangular aperture and introduces onto the hologram recording medium 3 the part of the object light L2 condensed by the cylindrical lens 28 that passes through the aperture.
A transmissive liquid crystal display 30 is also installed in a position between the collimator lens 26 and the projection lens 27. Element hologram images are sequentially displayed on the transmissive liquid crystal display 30, based on the element hologram image data D5 supplied by the control computer 12. The control computer 12 supplies a driving signal C2 to the recording medium feed mechanism 34 of the hologram recording medium 3, to be described in the following, and controls the feeding movement of the hologram recording medium by controlling its action.
In such an object optical system the object light L2, which has the form of a narrow beam incident from the incident optical system after splitting, is expanded by the spatial filter 25 and converted into a parallel beam by being introduced to the collimator lens 26. Further, in the object optical system the object light L2 that is made incident onto the transmissive liquid crystal display 30 through the collimator lens 26 is modulated as an image according to the element hologram image displayed on the transmissive liquid crystal display 30, and introduced into the cylindrical lens 28 through the projection lens 27. Then, in the object optical system, the object light L2 that is modulated as an image is made incident onto the hologram recording medium 3 through the aperture of the mask 29 during the time in which the action of the shutter mechanism 22 is to be open, thereby making an exposure and recording in correspondence with the element hologram image. In addition, as the reference optical system, the holographic stereogram printing module 13 has a spatial filter 31, a collimating lens 32 and a mirror 33, with each of these optical components sequentially arranged along the optical axis from the input side.
The spatial filter 31 is formed, in a different way from the spatial filter 25 in the object optical system described in a previous paragraph, for example, by combining a cylindrical lens with a slit, and one-dimensionally expands the reference light L3 split by reflection by the mirror 23 to a prescribed width, specifically to match the width of the display surface of the transmissive liquid crystal display 30.
The collimator lens 32 converts the reference light L3 expanded by the spatial filter 31 into a parallel beam.
The mirror 33 reflects the reference light L3 and guides it to the rear of the hologram recording medium 3 from which it is made incident on the medium.
The holographic stereogram printing module 13 with such an optical system is constituted in such a way that, after being split by the half mirror 23 the optical path lengths of the object optical system through which the object light L2 travels, and of the reference optical system through which the reference light L3 travels, are nearly the same. Therefore, in the holographic stereogram printing module 13 better coherence is achieved, making it possible to produce a holographic stereogram with a clearer reproduced image. The holographic stereogram printing system 10 is, in addition, equipped with a recording medium feed mechanism 34 that intermittently feeds the hologram recording medium 3 by the dimension of one element hologram at a time in the direction indicated by the arrow in
The recording medium feed mechanism 34 intermittently drives the translational movement of the hologram recording medium 3 based on the driving signal C2 supplied by the control computer 12. And the holographic stereogram printing system 10, in linked action with this action of the recording medium feed mechanism, operates the shutter mechanism 22 described in a previous paragraph to open the optical path of the laser light L1 based on the control signal C1 supplied by the control computer 12.
In such a holographic stereogram printing system 10, the hologram recording medium 3 is driven to undergo translational movement along a track by an amount corresponding to one element hologram at a time by having the control computer 12 supply driving signals C2 corresponding to each element hologram to the movement mechanism 34 after the completion of the exposure and recording of each element image, and then made to stop with an unexposed part aligned with the aperture of the mask 29. The holographic stereogram printing system 10 is constituted so that the vibrations generated in the hologram recording medium 3 which accompany the translational movement of said hologram recording medium 3 are rapidly stopped. Here, the hologram recording medium 3 is a photosensitive film in the form of a long sheet and, although not illustrated in the figure, it is, for example, wrapped around a supply roll disposed to rotate freely inside a film cartridge that is kept entirely shielded from light. When this film cartridge is mounted in the holographic stereogram printing system 10, the hologram recording medium 3 is paid out into the holographic stereogram printing system 10 and driven to undergo translational movement along the track by the recording medium feed mechanism 34.
In the holographic stereogram printing system 10 the shutter mechanism 22 is made to be open in this condition, letting the object light L2 which is modulated as an image and the reference light L3 be incident on the hologram recording medium 3 from the front and rear sides to expose and record interference fringes corresponding to the element hologram image, In the holographic stereogram printing system 10, upon completion of the exposure and recording of each element image, a driving signal C2 is supplied to the recording medium feed mechanism 34 by the control computer 12 to drive the hologram recording medium 3 to promptly undergo translational movement by a specified amount and stop.
In addition, in the holographic stereogram printing system 10 a development process including a process of UV irradiation of the hologram recording medium 3 and a process of heating the hologram recording medium 3 at a specified temperature is performed by a development process module that is not shown in the figure in order to fixate the holographic stereogram image that is exposed and recorded on the hologram recording medium 3. The holographic stereogram printing system 10 sequentially cuts the hologram recording medium 3, to which the fixation process has been applied, into each holographic stereogram image of a specified size that is externally discharged as a piece of holographic stereogram.
By subsequently performing this action sequentially, the holographic stereogram printing system 10 sequentially exposes and records a plurality of holographic stereogram images on the hologram recording medium 3 in the form of a long sheet to produce a holographic stereogram in which a sheet of holographic stereogram image has been exposed and recorded.
Next, in the following, a specific example of a holographic stereogram that is made as described above and of an illuminating device in which a variety of types of holograms can be mounted will be explained.
The variety of types of holograms include not only the Lippmann-type (volume-type) one-step holographic stereogram with horizontal disparity described above but also include such types as the full-parallax stereogram with vertical disparity also added, holograms produced by actual capture of such objects as models by laser illumination, replicated holograms using these as the original pieces, holograms of the type with surface relief referred to as embossed holograms and diffraction gratings. In the following, unless specifically stated otherwise, the holographic stereogram is also included as a type of hologram in referring to a hologram.
As a first embodiment of the invention, the penlight 500 as shown in
There are restricted areas 52 of the light-guiding diffuser 51 where the surface roughness is great, and the light incident from the end face 61 of the light-guiding diffuser 51 does not light the section with little surface roughness, but emerges by diffusion in the normal direction to the surface only in areas with great surface roughness. Although the surface roughness is made great by techniques such as sandblasting, etching and laser marking in this embodiment, various other techniques, not limited to these, may be used. Further, milky white material may be kneaded into the plate in restricted areas. Material such as colorant diffuser material, fluorescent paint, black-light-sensitive material or cellophane may be applied to the plate in restricted areas or entirely. An element such as a diffraction grating or a hologram of the surface-relief type or the Lippmann type may also be used. The shape may be not only a design such as a star-shaped pattern but forms such as letters or numerals.
In addition, a reflective hologram is attached either directly, or by means of a frame mount 62 as shown in
The whole light-guiding diffuser has a rotatable structure by being joined at the hinges 53. In the configuration of
The angle between the light-guiding diffuser 51 and the bracket 60 is variable from 0 degree to 45 degrees by rotation, and it is prevented from going beyond this range by stopper a 56 and stopper b 57. That is, the movable configuration can be changed continuously between the first form for illumination primarily for decoration and the second form for viewing the hologram, and it is prevented from reaching a condition outside this range.
In addition, a mechanism that is not shown in the figure allows the configuration to be fixed at 0 degree or 45 degrees unless a substantial external force is exerted. That is, there is a mechanism that allows the configuration to be fixed at each of the positions of the first form for illumination primarily for decoration and of the second form for viewing the hologram.
As the light source, a red LED 54a, a green LED 54b and a blue LED 54c are mounted inside the carrier for the light source. In the configuration of
In the configuration of
A switch such as a micro-switch or an optical switch that is not shown in the figure is disposed at the position of the stopper 56b or at the light-incident end face 61, and it may be made possible to change the control of lighting of the light sources 54a-c depending on the position of the light-guiding diffuser 51. In the configuration of
With the first embodiment, the efficiency is high since the same light source can be used for both the penlight functionality and the hologram illumination functionality by having the internally mounted red LED 54a, green LED 54b and blue LED 54c in the light source. In addition to this, there may be installed one or more white LEDs. In this case, variations are possible such as to have, in the configuration of
The layer composition of the hologram used in the first embodiment will be explained by illustrating its cross-sectional diagram in
For a hologram, it is important which side is front or rear, which side of the image is top or bottom and whether it is illuminated with light from an obliquely upward direction or an obliquely downward direction. Especially for a Lippmann hologram, since the interference fringes are formed by modulation of the index of refraction inside the recording layer, its orientations are difficult to recognize before illumination with the illuminating light. In the case that the hologram layer in the structure of
In the present invention, markings as shown in
Variations of the marking to indicate the optimum incident illuminating light are shown in
With regard to the marking shown in
In the present embodiment, the frame mount 62 is worked to have a shape that makes it possible to mount it correctly on the illuminating device without a marking of the recommended illuminating light. As shown in
On the other hand, a cylindrical protrusion 63 is formed in the illuminating device of the present embodiment, and the diameter of this cylindrical protrusion is smaller than the perforated hole 64 in the frame of the hologram medium. The hologram medium 70 is mounted by first putting it in place by having the cylindrical protrusion of the device inserted into the perforated hole 64, and then it is held in place by a clip 59. Incorrect insertion can be prevented because the perforated hole 64 of the hologram medium and the cylindrical protrusion 63 of the illuminating device do not match if an attempt is made to mount with an incorrect orientation in the top and bottom, left and right or front and rear direction and insertion is not possible. The protrusion may be not cylindrical but of such forms as a round hemispherical protrusion or a large cylinder with a large chamfer. In this way, it may act also as a stopper so that the perforated hole 64 and the protrusion 63 are engaged just by insertion by sliding along a guide and pushing in and, at the same time as having their positions determined, they are not naturally disengaged unless force is exerted to disengage them.
In the foregoing, an example was explained in which the orientation of the medium can be defined by a cylindrical protrusion and a perforated hole, but any device to uniquely determine the top and bottom, left and right and front and rear directions, not limited to this example, may be used. For example, the structure of the frame as a whole may be made to be asymmetrical, such as by making one of the four corners have a different shape from the others, with the illumination device being worked to match this shape. In the foregoing example, the hologram base material is made to be transparent so that the background can be seen through, but the background may also be made to be not easily visible by disposing a base material or adhesive material of a black or dark color on the side of the hologram recording layer 72 opposite the viewer. In this case, there are advantages such as better visibility of the hologram image with greater contrast and reduction of errors in distinguishing the front and rear sides. That is, on the side of frame B 75, the hologram part may be left with unworked base material for opacity rather than be made to have a perforated hole.
Various materials such as paper, plastic, metal and wood may be selected for use as frame A 74 and frame B 75 constituting the frame mount 62. Frame A 74 and frame B 75 are pre-connected to each other as a crease, and frame A 74 and frame B 75 can be pasted together in register by folding at the above crease upon positioning the hologram and attaching with an adhesive agent so that they cannot be detached again.
The adhesive agent may be of a type that allows subsequent detachment. In addition, frame A 74 and frame B 75 may also be attached together without using an adhesive agent by working them into shapes for fitting or folding together.
There is a perforated hole or a concavity at position 65 of the frame mount 62 to, by itself, allow attachment of a strap, a key, or an LED light source. If an LED light source of the type of a key holder is used in combination, simplified viewing is also possible. In addition, if the holes 65 of more than one frame mounts of holograms are tied together with a string or an elastic cord, they are not easily mislaid. If they are tied together with the illumination device that is the present invention, it is possible, by the intention of the viewer, to mount for viewing different holograms exchangeably. In order to achieve this purpose, the design of the illumination device of the present invention is devised so that the component that is joined at the position of the hole 65 in
With the first embodiment, the hologram can be viewed without being held manually when it is placed in the configuration of
Presuming the mode of viewing as shown in
When the embodiment illustrated in
As a second embodiment of the invention, the case of mounting a hologram medium constituted as in
In the case of the second embodiment, the problem may arise that the method of viewing is difficult to recognize without combining with the illumination device because the hologram medium used requires the illuminating light to be incident from a direction obliquely downward with respect to the viewer, which is different from the holograms in prevalent use. In contrast, in the present invention, as described above, the viewer is enabled to recognize the optimal illumination condition without confusion because markings such as in
In the second embodiment, in the case of mounting on a holding platform 81 as in
A third embodiment will be explained by using
When the hologram is not being viewed, the carrier for the light source for illuminating the hologram 151, as shown in
When the hologram is being viewed, as shown in
A fourth embodiment will be explained by using
By using a plurality of light sources such as L1 to L7 for illumination, when the hologram is illuminated beneficial effects can be expected as described above, and when they are incident to the light-guiding diffuser decorative effects and messaging effects can also be introduced such as, for example, to enhance the lighting of the letters “LIVE!” one letter at a time in the example in
In the structure of the fourth embodiment, the bracket 960 can be rotated together at the hinge, and when set down in such a place as a desktop upon putting it in a configuration such as in
A fifth embodiment will be explained by using
In other variations, instead of relying on gravitational force, elastic force such as the force of a spring, or an actuator such as a motor, may be used for driving.
A sixth embodiment will be explained by using
A plurality of LEDs are installed such as L1, L2-L7 inside the transparent hollow structure 610. A mirror 613 is disposed in the paths of the light emitted from, among these, LEDs L2, L4, L6 just after being emitted, and these are fixed to have orientations facing the center of the hologram. It is made possible to dispose them in a compact arrangement inside the hollow structure by using the mirror.
Since there is no mirror just after light is emitted from L1, L3, L5, L7, the hollow structure is illuminated from the inside, and elements in the form of prisms that facilitate oblique incidence of light are formed as a sawtooth structure in the vicinity of the part of the hollow structure that is illuminated by the LEDs, so that light is guided at an angle that is nearly parallel to the face of the hollow structure into the interior of the plastic material forming it. Since the angle exceeds the critical angle, if the transparent hollow structure is an ideal specular flat plate, light travels by total internal reflection inside the plastic material, as in the case of light-guiding, from the end face and no light exits from the surface. In the decorative diffuser section 611, minute bumps and dents are worked on the surface of the hollow structure so that only such parts are seen to be lighted.
Although housing the components such as the hologram and the light source inside the transparent hollow structure 610 enhances robustness by impeding the entry of such matter as dust and debris, the impediment in viewing the hologram due to the working of minute bumps and dents 611 is undesirable since the viewer sees the hologram through the hollow structure. Therefore, no light-diffusing element is made to be placed within the zone of directions from at least 20 degrees upward to 20 degrees downward, and from 45 degrees to the left to 45 degrees to the right, with respect to the normal to the center of the area of the hologram on the side of the viewer. This zone is specified since the zone in which a hologram can be viewed is dependent on the specification of the hologram and, in general, holograms for viewing which have viewing angles to the left and right are most often made for 20 degrees upward to 20 degrees downward, and from 45 degrees to the left to 45 degrees to the right. Also the gate used in the plastic molding process is made by locating it to avoid this position. The transparent hollow structure 810 is made of material with a total light transmittance of 80% or greater and a haze value of 10% or less in order to avoid degradation of the brightness and image quality of the hologram, and if there should be components with diffusing properties in some part, the area of the diffusing or opaque parts is kept to be 10% or less in order to avoid significant adverse effects in viewing the hologram.
The haze value is a measure of turbidity (opacity), given by the ratio of the diffuse transmitted light to the total transmitted light. It is specified in JIS-K-7105, JIS-K-7136.
Haze (%)=Td/Tt×100 (Td: diffuse transmittance Tt: total light transmittance)
Further, when there is unwanted reflection at the surface of the material of the hollow structure 810, the image may become darker due to the reduced amount of light contributing to the reproduction of the hologram, unwanted hologram images may be reproduced by the unwanted light, or the unwanted reflected light directly reaching the eyes of the viewer may be disturbing. In order to avoid this, in the present embodiment the surface of the hollow structure 810 is treated with such processes as antireflective coating or fabrication of a moth-eye structure.
Whereas decorative effect as a penlight can be exhibited by simultaneous or sequential blinking of L1, L3, L5, L7, the mode becomes that for viewing the hologram by turning on L4 alone. If L2, L4, L6 are sequentially turned on, it is possible to view the hologram image in motion without a need to move the illumination device or a need for the viewer to move.
In a variation, half mirrors may be placed in all of the paths of the light emitted from LEDs L1-L7 just after being emitted, in position 613, so that part of the light from each LED is used for illuminating the hologram and the remaining light is guided into the optical diffuser of the hollow structure. The ratio of the transmitted light to the reflected light of the half mirror may be different for each LED.
The rear side of the hologram, that is, the side opposite the viewer, is important. If an opaque black component is placed at position 616 in
By placing a louver film that is sold commercially for the purpose of privacy protection for cell phones and monitors at position 616 of the opaque member in
Next, the case of placing an anisotropic diffusing member at position 616 in
Lumisty is formed by at least two types of polymer compositions incorporating at least either photopolymerizable monomers or oligomers.
As photopolymerizable monomers or oligomers, for example, 2,4,6-tribromophenyl acrylate, tribromophenoxyethyl acrylate, 2-hydroxy-3-phenoxypropyl acrylate, tetrahydrofurfuryl acrylate, ethylcarbitol acrylate, pentenyloxyethyl acrylate, phenylcarbitol acrylate, polyol acrylate, polyacrylate with isocyanurate skeleton, melamine acrylate, polyacrylate with hydantoin skeleton and urethane acrylate can be cited.
As the individual polymer compositions constituting Lumisty, polymer compositions with refractive indices that are different from each other are used. As combinations of individual polymer compositions, for example, two types selected from monomers, or one type of monomer and one type of oligomer, or two types selected from oligomers, or one or more monomers or oligomers further added to these combinations can be cited. From the standpoint of securing adequate angle of diffusion of the diffused light, it is desirable that the difference between the refractive indices of at least two among the types of individual compositions in these combinations is 0.01 or greater.
As a composition constituting Lumisty, such agents as a photoinitiator, a plasticizer, a stabilizer, a filler material with an average particle diameter of 0.05-20 micrometers, an ultraviolet absorber, or a compound without photopolymerizability, may further be included.
When such an optically anisotropic diffuser is placed on the rear face of the hologram, whereas the rear becomes transparent to produce a see-through effect in viewing the hologram image, when seen from the direction of travel of the light from the LEDs there is no sense of glare since it becomes diffuse light and an effective decorative effect as a penlight can be enjoyed.
Although in the sixth embodiment the anisotropic opaque member or the anisotropic diffusing member is placed on the side of the illuminating device, it may also be placed on each hologram. That is, as shown in
The specifications such as the angle of the louvre are not limited to what is given here and, for example, one that blocks light from directly in front and passes light from an oblique direction may be installed. In this case, at the same time as improving the contrast in viewing the hologram, it also makes possible the use as a flashlight by letting the light from the LEDs be transmitted untouched. If this anisotropic opaque member or anisotropic diffusing member is placed on the side of the exchangeable medium rather than on the side of the illuminating device, it is made possible to enjoy a different effect with each medium.
As has been explained in the foregoing, as an example of placing a functional member such as an anisotropic opaque member or an anisotropic diffusing member, or a simple opaque member or diffusing member on the side opposite the viewer, the functional member may be placed either on the side of the illuminating device or on the side of the hologram medium. Further, the hologram medium, the functional member and the illuminating device are each separate from each other, and the hologram medium and the functional member may be made to be stacked and inserted into the illuminating device. Next, a seventh embodiment will be explained using the penlight 700 in
This avoids deterioration of image quality even if the surface roughness of the housing of the hollow structure is great. The entire housing may, rather, be an optically diffusing member. In addition, an optically diffusing member 721 in the form of a sponge is installed on top of the housing, and LEDs LX1 and LX2 for illuminating this are installed in addition to the light sources L1-L7 that illuminate the hologram. The lower part of the handle module is made greater in diameter, and viewing is also possible by placement on a surface such as that of a table.
Next, an eighth embodiment will be explained using the penlight 800 in
Next, a ninth embodiment, in the form of a hologram with a fluid hourglass, will be explained using the penlight 800 in
There is a notch in the flange that is not shown in the figure and, since there is also a similar notch diametrically opposite on the other side, the hologram is fixed at the correct position by a positioning component that is not shown in the figure.
Silicone oil is used as the filling fluid. The speed of movement of the decorative diffuser chips can be made slower by using oil with a high viscosity. Although the gap between the transparent hollow spherical body B 180 and the transparent hollow spherical body A 809 is made nearly uniform in
If the hologram is a Lippmann hologram with multiple recordings made with multiple exposures from different angles of the reference light, or one with two hologram sheets with different angles of the reference light stacked together, it is also possible to reproduce a different hologram image when inverted by 180 degrees.
A tenth embodiment will be explained using the cylindrical illuminating device 850 in
An eleventh embodiment will be explained using the penlight 750 in
The front face 773 of the housing is composed of a curved surface with curvature. In this case, the presence of a difference in curvature between the external side, that is, the side of the viewer and the internal side, the side of the hologram, results in enlargement or diminution, or distortion of the image by acting in the manner of a lens effect. In the case that a known distortion is generated, it is also possible to perform image processing in advance on the image data for recording to compensate for the distortion.
A twelfth embodiment will be explained using the hologram illumination device 300 in
First, the penlight module 350 will be explained using
The lens 377, the prism sheet 375, the reflecting mirror 376 and the hologram support unit are mounted on an oblate spheroidal housing 360, and the housing 360 and the handle module are made to be attachable by a threaded part that is not shown in the figure. The housing 360 is made to be transparent only in the part 373 for viewing the hologram and since optically diffusive components are coated on, or placed adjacent to, the remaining part, a decorative effect can be provided by illumination with the part of the light that is not utilized for illumination of the hologram or with a separate light source that is not shown in the figure.
If the light from the LED light source 374 passes through the transmissive components such as the lens 377 and the prism sheet 375 and directly exits from the optical aperture 373 of the housing, there may be excessive glare or degradation of the decorativeness, but light that is so bright as to be glaring is made to be not directly visible, even in intentionally looking into the light source, by installing a shielding plate 378.
The shielding plate 378 may be decorated with such features as letters. It is not necessary for the shielding plate 378 to be optically totally opaque, and it may be made of a diffusive body or have a partial optical aperture.
In the present invention, the reason for first deflecting the light from the light source that is emitted in the direction of the cylindrical axis of the handle module is that in a great majority of existing flashlights and penlights, light is emitted in the direction of the cylindrical axis of the handle module. That is, it can be used as a flashlight by detaching the housing 360 in
In other words, it is made possible to easily put together a device for viewing a hologram by installing the housing 360 of the present invention with the necessary optical components, light diffuser and hologram mounted inside.
When a high-intensity power LED rated at 1W or greater is used as the LED light source 374, in some cases there is a sense of glare when the light enters the eyes directly without diffusion or blocking. Since, if the replacement as described above is left up to the user there is a possibility that damage is caused in the eyes by accidentally looking at the bright light against intention during the replacement, a switch is put in the mounting part that makes an interlock mechanism function to disable light emission in the condition of the housing 360 in
Although, in the present embodiment, a prism sheet is used to deflect the light emitted in the direction of the cylindrical axis and a reflecting mirror is used to deflect it again in the direction of the hologram, for either of these, components may also be used such as a reflecting mirror, a prism in block form, a lens, a diffraction grating, a holographic device, an electro-optic modulation device or an acousto-optic modulation device.
Although the relative relationships of position and angle between the hologram and the light source are fixed in the penlight 350 by itself, when the whole penlight 350 is placed on the dedicated holding-stand-cum-rocking-device, motion can be viewed also by a stationary viewer. An example of the holding-stand-cum-rocking-device will be explained using
That is, continuous rocking as described above can be realized by repetitive control to alternate a time period in which current is made to flow in the electromagnets so that the weight 393 and the counter-posed electromagnet 395 repel each other and/or the weight 394 and the counter-posed electromagnet 396 attract each other, with a time period in which, conversely, current is made to flow in the electromagnets so that the weight 393 and the counter-posed electromagnet 395 attract each other and/or the weight 394 and the counter-posed electromagnet 396 repel each other.
It is not necessary to drive the rocking by electrical means, but spiral and helical springs with elastic force can also be used as the driving force. Further, gravitational force alone may be utilized to cause rocking in the manner of a swaying balancing toy. A thirteenth embodiment will be explained using
A fourteenth embodiment will be explained using the hologram illumination device 250 in
The hologram may be attached to the glass plate on the side of the viewer, or it may be attached on the side opposite the viewer and further, it may be disposed so that it is sandwiched among a plurality of glass plates. Different light sources are placed in different positions, and it is also possible to provide different sequences of decorative as well as dramatic presentation effects such as by turning them on sequentially, illuminating, for example, the optical diffuser in the background with an underlying blue tone when the first hologram is illuminated and illuminating the optical diffuser in the background with an underlying red tone when the second hologram is illuminated. In the case that the hologram is attached to the glass plate on the side opposite the viewer, an acrylic member 254 that is formed like ground glass is placed further behind it. The surface of this acrylic member is decorated by laser processing and the part that is processed is highlighted when illuminated by light. The acrylic member 254 is illuminated by light from the red, green and blue LEDs mounted inside the casing 262. In this way, it is possible to enhance the decorativeness of the hologram by illuminating with light from inside or outside the base material on which the hologram is attached.
A clock 253 is embedded in a part of the glass plate 252. Items may also be installed, not limited to an analog clock as shown in the figure, such as a clock with digital display, a thermometer, a hygrometer, a calendar, a photo display, an LCD or several of these in combination.
The glass plate 252 may also be made of, not glass, but a material such as those described above that contain plastic material such as acrylic, polycarbonate or polystyrene resin, or a phosphor material.
As it has been explained in all the embodiments described in the foregoing, from the first to the fourteenth, the light source to be incident to the optical diffuser and the light source for illuminating the hologram may either be the same, or be separate. Even in the case that they are separate, upon using the power supply section, such as the battery, in common, the balance between the amounts of power supplied to the light sources is made to be different when illuminating or not illuminating the hologram, in order to save power consumption.
Since the prominence of the hologram image is lost if the light illuminating the optical diffuser is too intense, linked operation is executed such as to reduce the light illuminating the optical diffuser only when viewing the hologram. That is, dramatic presentation effects of lighting that changes with time may also be provided, such as to first make, upon turning on the switch, the optical diffuser be lighted with various colors and brightness by sequential intense illumination by each of the red, green and blue LEDs with different timing, then to make a plurality of LEDs for illuminating the hologram be sequentially lighted, then to make the red, blue and green LEDs for illuminating the optical diffuser become slightly brighter at the same time as slowly darkening the LEDs for illuminating the hologram, and then turning off all of the LEDs.
In the embodiments described above, examples were cited of cases in which the predetermined angle of the device was 45 degrees to match the optimal angle of illumination of the hologram. That is, in the condition of illuminating the hologram support unit described above, the angle between the line joining the light source described above and the center of the hologram or holographic stereogram described above and the normal to the surface of the hologram or holographic stereogram described above is set to be 45 degrees upward, or 45 degrees downward with respect to the viewer, but it is not limited to these values. Preferably, the support should be with the angle described above maintained to be a predetermined angle between 40 degrees and 70 degrees upward or between 40 degrees and 70 degrees downward. An angle that is less than 40 degrees is undesirable because the light from the light source would be more likely to enter the eyes of the viewer, An angle that is greater than 70 degrees is undesirable because, whereas the illumination device is made to be compact, viewing of a bright hologram image would be made more difficult due to the greater surface reflection at the hologram surface.
In the embodiments described above, components such as an opaque member, an absorbing member, a diffusing member, or combinations thereof, that are not shown in the figure are placed in the vicinity of the light source on the side of the viewer because the light from the light source, if it reaches the eyes of the viewer without being blocked, absorbed or diffused, results in glare that disturbs viewing.
Although the first to the twelfth embodiments to which the invention is applied have been described in detail above, the present invention is not limited to the embodiments described above and various modifications can be made based on the technical concepts of the present invention.
For example, in a third variation, the basic constitution is the same as in the third embodiment, and the light-guiding diffuser may also be made in the form of a round fan with a radiating skeletal structure.
Or, it is also possible to make, for example, the battery for the light source replaceable, or the light source replaceable by adopting a socket-type arrangement.
Further, in the cases of a display of merchandise or of use as POP (point of purchase advertising) in the shop, power may also be supplied from an outlet, mediated by an AC adaptor voltage converter, since a battery requires replacement during an extended period of display.
Further, a solar cell may be incorporated to dispense with the use of dry-cell or button-cell batteries.
LEDs are cited as an example of the light source, but self-luminous devices such as lamps including krypton, xenon and halogen lamps, lasers, fluorescent lamps and organic LED devices may also be used. Although examples incorporating, as LEDs, one each of three types of LEDs, red, green and blue, are described in the first to the third embodiments, a single white LED may also be used.
Although such materials as glass and cast acrylic material with good laser processability are suitable for use as the base material for an optical diffuser, materials not limited to these, such as polymer resin materials including polycarbonates and polystyrenes may also be used. Further, it is possible to provide visual effects of colors that are not necessarily the same as those of the wavelengths of emission of the LEDs if it is made, even just partially, with materials such as a variety of phosphors or materials that are luminous under black light,
In addition, the member to be placed in the hologram support unit is not limited to the card type, but any member incorporating a hologram and held in a condition that allows viewing may be applied, such as a key holder or a sticker.
Furthermore, although, in the embodiments described above, explanations are given of cases in which a member such as a holographic card can be freely removed, if intended by the viewer, from the hologram support unit, and in which it is attached by such means as an adhesive agent or a double-sided adhesive tape that is non-redetachable, it may also be arranged that, at first, a single hologram is attached in a non-redetachable manner, next to which it is possible to mount another hologram on top by the intention of the viewer. It may be made possible to house a plurality of holograms inside the illumination device and to view each hologram medium by mounting it, in turn, on the hologram support unit by the intention of the viewer.
A device for playing sound may be incorporated in the present illuminating device. It is also possible to play such sounds as the voice of a person or the cry of an animal that is the subject of the hologram.
A microphone for sound collection may be incorporated in the present illuminating device. In particular, if sound can be collected in the configuration of the eighth embodiment, utilization as a microphone for such use as in karaoke is possible.
The present illumination device may have a communication link. External control of the status is also possible, such as control of the mode of lighting, as well as turning on, flashing, and turning off the light. It is also possible to control a plurality of illuminating devices at the same time. It is also possible to control the light in accordance with various dramatic presentations such as music and environmental sound.
In the present illumination device, it is also possible to incorporate such sensors as a human body sensor that utilizes such means as infrared rays, ultrasound or visible light to detect temperature changes caused by the movement of a body, with a temperature difference from the surroundings, in the vicinity of the illumination device, to turn on the light source for viewing the hologram or to perform a rocking motion only when a viewer is present, and to turn off the light as well as stop the motion in the absence of a viewer. The present illumination device may have an accessory component with a hook shape, or it may be processed to have a through hole, for ease of hanging. This enables its use as an ornament for such decorations as a Christmas tree or by attaching a key holder or a strap.
Number | Date | Country | Kind |
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2012-180691 | Aug 2012 | JP | national |
2013-000249 | Jan 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/071827 | 8/12/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/027644 | 2/20/2014 | WO | A |
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20150205261 A1 | Jul 2015 | US |