A system for displaying, to viewers who do not need to wear special eyewear, static three dimensional (3D) images that are dynamically augmented with two dimensional (2D) images. The system includes a holographic print with a front surface and a back opaque layer. The system includes a projector projecting light onto the front surface. The projected light includes first light reconstructing a hologram from the front surface of the holographic print and second light displaying 2D content on the front surface. The projector is positioned to cause the first light to strike the front surface within a range of hologram reconstruction angles. The projector is a video projector, and the first light is even illumination in the form of white light while the second light includes the displayed 2D content. The displayed 2D content includes animation or video content.

A system for displaying, to viewers who do not need to wear special eyewear, static three dimensional (3D) images that are dynamically augmented with two dimensional (2D) images. The system includes a holographic print with a front surface and a back opaque layer. The system includes a projector projecting light onto the front surface. The projected light includes first light reconstructing a hologram from the front surface of the holographic print and second light displaying 2D content on the front surface. The projector is positioned to cause the first light to strike the front surface within a range of hologram reconstruction angles. The projector is a video projector, and the first light is even illumination in the form of white light while the second light includes the displayed 2D content. The displayed 2D content includes animation or video content.

A hologram module includes a phosphor layer and a rainbow hologram sheet. The phosphor layer has a phosphor array structure. The rainbow hologram sheet has a first display layer and a second display layer. The first display layer is disposed on the phosphor layer and has a first barcode array corresponding to the phosphor array structure. The second display layer is disposed on the first display layer and has a second barcode array corresponding to the first barcode array. The phosphor array structure, the first barcode array and the second barcode array are chromatic. A color of the phosphor array structure meets with a color combined by the first barcode array and the second barcode array so as to display a hologram image converted from light emitted by the phosphor array structure via the first and second barcode arrays.

A hologram module includes a phosphor layer and a rainbow hologram sheet. The phosphor layer has a phosphor array structure. The rainbow hologram sheet has a first display layer and a second display layer. The first display layer is disposed on the phosphor layer and has a first barcode array corresponding to the phosphor array structure. The second display layer is disposed on the first display layer and has a second barcode array corresponding to the first barcode array. The phosphor array structure, the first barcode array and the second barcode array are chromatic. A color of the phosphor array structure meets with a color combined by the first barcode array and the second barcode array so as to display a hologram image converted from light emitted by the phosphor array structure via the first and second barcode arrays.

A light modulation element reproduces a light image in a specific color other than iridescence where white light is incident, without a layer that selectively transmits or reflects a specific wavelength band, and clearly reproduces a desired light image by reducing an influence of 0th-order diffracted light, and an information recording medium including the same. The light modulation element includes a factor element that reproduces a light image by modulating a phase of incident reproduction light, and has an uneven surface. A maximum diffraction efficiency Dmax in a wavelength band of between 380 nm and 780 nm in wavelength distribution of first-order diffracted light and of negative first-order diffracted light with respect to diffraction efficiency for the factor element has a local maximum value with a full width at half maximum FWHM of 200 nm or less in wavelength distribution with respect to diffraction efficiency having the maximum diffraction efficiency.

A method is provided for producing a hologram for a retroreflector. A retroreflector is provided containing numerous facets, each of which reflects light. A photosensitive recording material is applied to the retroreflector. A laser beam is generated, and numerous facets of the retroreflector are successively lit with the laser beam through the recording material, such that the laser beam is reflected by each of the facets and then passes back though the recording material. The laser beam that moves through the recording material toward the facet is a reference beam, and the laser beam reflected back by the facet forms an object beam, such that a segment of the hologram is generated in a part of the photosensitive recording material in front of each of the facets by superimposing the laser beam moving toward the facet with the reflected laser beam.

A method is provided for producing a hologram for a retroreflector. A retroreflector is provided containing numerous facets, each of which reflects light. A photosensitive recording material is applied to the retroreflector. A laser beam is generated, and numerous facets of the retroreflector are successively lit with the laser beam through the recording material, such that the laser beam is reflected by each of the facets and then passes back though the recording material. The laser beam that moves through the recording material toward the facet is a reference beam, and the laser beam reflected back by the facet forms an object beam, such that a segment of the hologram is generated in a part of the photosensitive recording material in front of each of the facets by superimposing the laser beam moving toward the facet with the reflected laser beam.

We fabricate a stereoscopic hologram of an object by capturing a sequence of 2D images of the object, moving camera along a linear axis past the object and keeping the optical axis of the camera perpendicular at each of the positions. The camera lens and image recording surface are translated along the axis such that a fiducial part of the image does not move. The sequence is replayed and a first volume hologram is recorded by recording holograms of the captured images on a diffusing screen in different spatial locations on a surface of the first volume hologram. This is then replayed to form a stereoscopic image of the object and a second, volume reflection hologram of the replayed image is recorded to provide the stereoscopic hologram. A central image of the sequence is aligned to the fiducial part of the holographic image to make the resulting hologram user-friendly.

We fabricate a stereoscopic hologram of an object by capturing a sequence of 2D images of the object, moving camera along a linear axis past the object and keeping the optical axis of the camera perpendicular at each of the positions. The camera lens and image recording surface are translated along the axis such that a fiducial part of the image does not move. The sequence is replayed and a first volume hologram is recorded by recording holograms of the captured images on a diffusing screen in different spatial locations on a surface of the first volume hologram. This is then replayed to form a stereoscopic image of the object and a second, volume reflection hologram of the replayed image is recorded to provide the stereoscopic hologram. A central image of the sequence is aligned to the fiducial part of the holographic image to make the resulting hologram user-friendly.

Disclosed herein a light projection device and a head lamp for vehicle capable of highly increasing and decreasing the illuminance of a plurality of specific regions in a light distribution designed in advance with high degree of freedom. The light projection device includes: a first optical system that forms a second light radiation region; a dynamic light deflection unit configured to deflect a light beam involved in forming the second light radiation region; a second optical system configured to project the deflected light beam to form a third light radiation region; and a deflection pattern generation unit configured to deflect and output each ray of the light beam such that a direction of deflection to be imparted is dependent on a position at which each ray is incident on the light incident portion.