Abstract: A system, device within a system, and a method for enhancing visual perception in a two-dimensional image is disclosed, providing the induction of retinal disparity in the viewer by a device with which the two-dimensional image is viewed. With fusion of the retinally disparate images of the two-dimensional image, the viewer experiences the enhancement of his or her visual perception in the two dimensional image, which includes enhancement of depth perception and enhancement in clarity perception.

Abstract: A three-dimensional display device includes a two-dimensional display displaying a first image, and a variable focusing lens receiving light from the two-dimensional display and forming a second image. The variable focusing lens reflects light from the two-dimensional display. The first image includes a predetermined number of first depthwise images that are displayed within a unit time, and the second image includes corresponding second depthwise images. Each depthwise image represents the portion of the first image having the same image depth, and the two-dimensional display displays one depthwise image at a time. The focal length of the variable focusing lens changes according to the depth of the depthwise image being displayed. A micromirror array lens is used as the variable focusing lens. The micromirror array lens has enough speed and focusing depth range for realistic three-dimensional display.

Abstract: A system, device, and method for enhancing depth perception in a two-dimensional image is disclosed providing the induction of retinal disparity in the eyes of the viewer by the placement of a visually identifiable object in front of the two-dimensional image. Upon fusion of such retinal disparity in the viewer, the viewer experiences the enhancement depth perception in the two dimensional image.

Abstract: A display unit for displaying first and second images includes a display device, a parallax barrier arranged facing the display device, and a lenticular lens arranged facing the parallax barrier. The parallax barrier includes a plurality of slit regions. A slit control section alternately switches each slit region between a transmitting state and a shielding state at a predetermined cycle. An image signal output section provides, in synchronization with the switching of the slit region, image data to the display device so that the plurality of pixels of the display device display an image different from the image displayed before switching of the slit region.

Abstract: An improved object projection system provides an observer with a surrounding background that has adjustable contrast levels relative to an object. A transmissive polarizer and a reflective polarizer change relative orientations. The change in orientation causes the level of light passing through the transmissive polarizer to change. In one system, the transmissive polarizer is placed in front of an object. A light source is placed in front of the object and behind the transmissive polarizer. A reflective polarizer is placed behind the object. The reflective polarizer provides the surrounding background for the object. A light source illuminates the object and the reflective polarizer. The object emits reflected light, which travels through the transmissive polarizer. Light from the reflective polarizer is transmitted to the transmissive polarizer. The level of light transmitted depends on the orientation of a transmissive axis of the transmissive polarizer to a reflective axis of the reflective polarizer.

Abstract: An apparatus and method are provided for producing images having a depth or relief component (e.g., appearing three-dimensional) from single perspective projection masks. The three-dimensional relief images are generated from two-dimensional images utilizing a simplified electromechanical device. In this regard, an oscillating light redirecting system is used to synthesize a third dimension onto a two-dimensional image resulting from projecting light through a single perspective projection mask. The light redirecting system controllably deflects the light projecting through the projection mask about two axes prior to the resulting image being projected on a surface. When projected onto a surface, the resulting image is controllably spread over two axes such that it appears to be a three-dimensional relief image. In a further embodiment, color filtering is utilized in order to produce color three-dimensional relief images.

Abstract: An improved real image projection system comprises, in the primary configuration, a tilted mirror to eliminate ghost reflections, and a unique arrangement allowing the introduction of a second background image without a 50%/50% beamsplitter, while providing system transmission of approximately 50%. A secondary configuration incorporates an elliptical or aspheric curved mirror designed to simulate the surface of a spherical curve when light strikes the elliptical surface at an angle equal to the elliptical angle of the curved mirror. In a third configuration, a single curved mirror has two different optical surfaces of revolution, one on the convex surface and one on the concave surface. The concave surface is much like that of a Mangin lens, but it has an aspheric surface of revolution, optimized to reduce spherical aberrations over a larger area offset from the optical axis.

Abstract: An autostereoscopic display comprises an SLM which is controlled to provide an image display and a signal display. A parallax optic has a first portion which cooperates with the image display to form a plurality of viewing windows. A second portion of the parallax optic forms first and second images visible to an observer to allow the observer to distinguish between a desired orthoscopic viewing zone and undesirable viewing positions such as pseudoscopic positions. The pitch of parallax elements in the second portion is one and a half times the parallax element pitch in the first portion.

Abstract: The invention relates to a projection viewing system of simplified construction and high illumination efficiency, which enables at least two of images varying with viewing directions to be simultaneously displayed in a viewable fashion. The system comprises display devices 1L and 1R for displaying images, projection optical systems 2L and 2R for magnifying and projecting images 3L and 3R displayed on the display devices 1L and 1R, a diffusing plate 5 located in the vicinity of images projected through the projection optical systems 2L and 2R and an eyepiece optical system 4 for projecting exit pupils of the projection optical systems 2L and 2R on the positions of the eyeballs of a viewer. The diffusing plate 5 has an angle of diffusion of up to 20° at full width half maximum.

Abstract: An apparatus for showing images. The apparatus includes a screen. The apparatus includes a mechanism for displaying a distinct and separate image for each of a number of different observers simultaneously on the screen. A method for showing images.

Abstract: A teleprompter configured to project an image to a viewer at a viewer location comprises a single-beam teleprompter projector, configured to project an image to a focal plane, and a directional screen, disposed at the focal plane. The directional screen is configured to direct the image to a focal point at the viewer location, and diffuse the image within a limited viewing region surrounding the focal point, such that the apparent brightness of the image to the viewer at the viewer location is increased, and the visibility of the image to persons other than the viewer is reduced. Because the device concentrates the light at the viewer, it can be made much larger than conventional video monitors typically used in speech-prompter settings, while still maintaining very high brightness.

Abstract: A display unit for displaying first and second images includes a display device, a parallax barrier arranged facing the display device, and a lenticular lens arranged facing the parallax barrier. The parallax barrier includes a plurality of slit regions. A slit control section alternately switches each slit region between a transmitting state and a shielding state at a predetermined cycle. An image signal output section provides, in synchronization with the switching of the slit region, image data to the display device so that the plurality of pixels of the display device display an image different from the image displayed before switching of the slit region.

Abstract: A monocentric arrangement of optical components providing stereoscopic display of a virtual image, electronically generated, line by line, from an electromechanical grating light modulator (85) and projected, as a real intermediate image, near the focal surface (22) of a curved mirror (24) by means of a scanning ball lens assembly (100). To form each left and right intermediate image component, a separate image generation system (70) comprises a scanning ball lens assembly (100) comprising a spherical lens (46) for wide field of view and a reflective surface (102). A monocentric arrangement of optical components images the left and right scanning ball lens pupil at the corresponding left and right viewing pupil (14) of the observer (12) and essentially provides a single center of curvature for projection components.

Abstract: Apparatus for producing aerial-images is disclosed employing a combination of focusing reflectors, beamsplitter polarizing filters, and light sources. An object to be displayed is illuminated, and its image partially reflected by the beamsplitter to a focusing mirror and reflected to an aerial position. A polarizer prevents ambient light or images from degrading or interfering with the aerial-image. A clock radio, personal television display counter, as well as animated mannequin versions are disclosed.

Abstract: An image display apparatus includes a light source for supplying illumination light, a reflection type display device which reflects the illumination light and modulates the illumination light into image light, and an illumination optical system for guiding the illumination light to the reflection type display device. The illumination optical system includes a first optical member for directing the illumination light toward the reflection type display device, and a second optical member. The second optical member includes a part generating a secondary light source with the illumination light emitted from the light source, in which the light from the part emerges toward the first optical member, and a reflecting surface which guides illumination light which is not incident directly on the part to the part. In addition, a projection optical system guides the image light to an observer.

Abstract: An apparatus for producing a volumetric display includes a scanning collimated light source that creates an image by illuminating a suspension of light-scattering particles in an optically transparent medium with a collimated beam, where the brightness of the collimated beam is modulated at each moment in time by an amount that is dependent upon the momentary direction of the beam and also on the distance of the scattering particle encountered by the beam at that moment. A method for producing a volumetric display. An apparatus for producing a volumetric display includes a light source for providing light. The apparatus includes a mechanism for producing a volumetric image with the light from the light source. The method includes the steps of producing light from a light source. There is the step of producing a volumetric image with the light from the light source.

Abstract: An image display device has a luminous image source operably positioned within a housing for projecting a projected image. The housing has a lens aperture covered by a lens assembly. The lens assembly is spaced apart from the luminous image source so that the lens assembly functions to projecting the luminous image outside of the internal chamber and beyond the lens assembly to appear as the image bubble that includes the projected image. The lens assembly includes a first lens, a second lens adjacent the first lens, and a third lens adjacent the second lens. The first lens has a first focal length that is approximately one-half of a focal length of the second or third lenses.

Abstract: An aerial projection system and method having a housing for positioning low cost optical elements capable of generating a three dimensional aerial images at video rates without reflected artifacts or visible display of the display screen. A method for generating the display images is based on a set of rules that eliminate boundary transgressions and maximizes the illusion of a three dimensional aerial image. An optional second display is a transparent imaging panel that acts selectively as a light valve, as a display platform for special effects or for providing the appearance of linear motion towards or away from the observer. An optional third display, also a transparent imaging panel, may be used as a background display device for displaying video rate images that are not projected aerial images.

Abstract: A projection system configured to project a stereographic image onto a viewing surface is provided. The projection system includes a light source configured to produce a beam of light, a beam splitter configured to split the beam of light into a right image beam and a left image beam, an image engine configured to produce the stereographic image, and a projection lens configured to project a left-eye image and a right-eye image onto the viewing surface. The image engine includes a left optical path configured to produce the left-eye image from the left image beam, the left optical path including an upstream left polarizer, a left image-producing element and a downstream left polarizer, and a right optical path configured to produce the right-eye image from the right image beam, the right optical path including an upstream right polarizer, a right image-producing element and a downstream right polarizer.

Abstract: A system and method for providing images for an operator of a vehicle include the capability to receive electrical signals representing electromagnetic radiation at an image source and to generate a visual image based on the electrical signals. The system and method further include the capability to reflect different portions of the visual image with a magnifying optical element for presentation at different viewing locations, the visual image appearing as a virtual image, wherein at least one dimension of the visual image is larger than the magnifying optical element can use to present an image at one of the viewing locations.

Abstract: A real image projection system is provided including a projection system housing with an aperture. This device provides a real image projected into a viewable volume of space relative to the aperture. An optical assembly and an object positioning device adjacent to the optic assembly provide the real image. The object positioning device may position an object adjacent to the optic assembly in dynamic or static fashion. The optical assembly receives the light rays reflected from the object and projects a real image of the object into the viewable volume of space. The invention provides environmental visual cues to promote perception of a three-dimensional image. The invention further includes a secondary mirror for use in reducing or minimizing the overall size of the system housing.

Abstract: A monocentric arrangement of optical components providing stereoscopic display of a virtual image, electronically generated, line by line, from an electromechanical grating light modulator (85) and projected, as a real intermediate image, near the focal surface (22) of a curved mirror (24) by means of a scanning ball lens assembly (100). To form each left and right intermediate image component, a separate image generation system (70) comprises a scanning ball lens assembly (100) comprising a spherical lens (46) for wide field of view and a reflective surface (102). A monocentric arrangement of optical components images the left and right scanning ball lens pupil at the corresponding left and right viewing pupil (14) of the observer (12) and essentially provides a single center of curvature for projection components.

Abstract: The present invention relates to a display device with variable focusing depth. The display device presents from electrical signals an image built up of at least two sub-images for the eye (7) of an observer. Focusing depth is generated in the image by different sub-images being generated with different focal distances and that objects in the image are distributed in the sub-images with regard to the depth effect one intends to create in the image.

Abstract: A system for displaying graphical information in three dimensions. The system includes a host device executing an application for generating graphical information in a spatial transport protocol. Rendering hardware generates three-dimensional display data and a frame buffer stores the three-dimensional display data. A spatial display displays the three-dimensional display data. A spatial transport protocol interpreter receives the graphical information in the spatial transport protocol and controls operation of the rendering hardware and the frame buffer in response to the graphical information in the spatial transport protocol. An architecture for displaying graphical information in three-dimensions is also provided.

Abstract: The present invention relates to projection systems for displaying visual information in a variety of applications in order to reduce the projection area, the weight and the dimensions thereof. In one embodiment, the projection system for producing an external surface projection on a visualization screen comprises a flat and thin visualization screen for carrying out projection on both sides. Images can be watched on the left side and on the right side of this screen. From the surface of the screen and on the left and right sides thereof, projectors are provided for projecting images simultaneously on both sides of the screen. Light diffusers are provided on both sides of the screen. The projections are converted through the optics of the projectors so as to form reduced-divergence projection beams which are entirely captured by the light diffusers and which are diverted and diffused at wide angles of image observation ranges.

Abstract: A display system is disclosed. The display system includes a processor and a first display device having a first display surface and receiving display data from the processor. The display system also includes a second display device having a display area smaller than the first display device and moveable over the surface of the first display device. The second display device is either partially transparent or partially translucent. The display system also includes a sensor in communication with the processor and communicating location data to the processor. The location data is representative of the relative location of the first display to the second display. A program is configured to run on the processor and provides display data to the first and second display devices such that the display data prior to the second display device is based on the location data. A user of the system views a composite three-dimensional image when viewing the second display.

Abstract: A monocentric image generation system (100) for forming a curved image (110) using a spherical mirror (92), a beamsplitter (102) and a ball lens assembly (30) and, optionally, a field lens (112). An image source (94) provides a source image through an aperture stop location (96) at the center of curvature Cs of the spherical mirror (92). The beamsplitter (102) provides the resulting intermediate image (90) so that it is concentric with the ball lens assembly (30) in order to form the curved image (110).

Abstract: An image projection system includes an image generator and first and second projection screens. The image generator respectively generates the first and second portions of the image on the first and second projection screens. The first projection screen projects the first portion of the image in a first color, and the second projection screen projects the second portion of the image in a second color. Such an image projection system is often less complex and less expensive than a conventional image projection system such as a projection television system. In addition, such a projection system often provides a higher-quality image than a conventional image projection system.

Abstract: A pixel element for a 3D display, wherein multiple substantially collimated controllable light beams are emitted in multiple directions, with each light beam associated with a predetermined viewing direction. A set of substantially point type sources are individually addressable and are arranged in a line. The light sources are serially addressed; and the light from each source is imaged in a collimated light beam and deflected in a predetermined individual deflection direction.

Abstract: A real image projection system includes at least one curved reflector, positioned in a tilted configuration, wherein an optical axis of the reflector is not coincident with a viewing axis, and a beampath between a target source and the curved reflector neither passes through nor reflects off of a beamsplitter.

Abstract: A screen display apparatus is capable of visually presenting to a viewer E a secondary image 30 (virtual image and/or a real image) as an “inclined” a primary image (subject) 10, and is vertically inclined with respect to said viewer at a position, which is different from a position of said primary image 10. This is realized through an action of a lens 20. With the “inclination, the viewer E views the secondary image 30 with a three-dimensional feeling. The “inclination” is effective when the upper part of the secondary image 30 is located farther from the viewer E than the lower part thereof, and when its angle &thgr; is within a range of 3° to 40°. Further, a screen display apparatus, a plurality of secondary images 30 (in the figures, virtual images 31 and 32) on a primary image 10 as a subject are formed by a microlens array 20 including convex microlenses 221 and concave microlenses 223.

Abstract: A substantially monocentric arrangement of optical components provides stereoscopic display of a virtual image, electronically scanned by resonant actuation of a resonant fiber scanner (137) using a flexible optical waveguide and projected, as a real intermediate image, near the focal surface (22) of a curved mirror (24) by means of a ball lens assembly (30). To form each left and right intermediate image component, separate left and right image generation systems (70) each comprise a resonant fiber scanner (137) that itself comprises a resonant cantilever portion (139) of optical fiber (138) that directs a modulated beam onto a curved surface (40) for projection by a ball lens assembly (30). A monocentric arrangement of optical components images the left and right scanning ball lens pupil at the corresponding left and right viewing pupil (14) of the observer (12) and essentially provides a single center of curvature for projection components.

Abstract: By this invention, multi-users can view the 3 dimensional objects or images in real time (run time) with high resolutions without special glasses in the space or in the air due to the fast movement of voxels projected by voxel projector means.

Abstract: A video projection system employing a concave video screen which provides for enhanced depth cueing. A method of designing a variety of shapes of video screen surfaces by varying certain parameters of a common master equation. Video screen surface shapes providing optimum viewing for specific applications.

Abstract: A real image projection system comprising two or more optical surfaces of revolution, with at least one comprising an aspheric surface of revolution. The aspheric surface of revolution is of a design to reduce natural aberrations inherent in imaging using surface of revolutions of the conic family of curves.

Abstract: Disclosed herein are three-dimensional projection systems and related methods employing two electronically controlled projectors and a retro-reflective screen. The retro-reflective screen produces a known non-linear light reflection pattern when images are projected thereon. Image computational means are used to calculating flat image information for each projector based upon inputted stereopair images and information regarding the projectors and screen. In preferred embodiments of the present invention, the projection system uses an image computational device that employs a neural network feedback calculation to calculate the appropriate flat image information and appropriate images to be projected on the screen by the projectors at any given time. More than two projectors can be employed to produce multiple aspect views, to support multiple viewers, and the like. In another embodiment, the projection system includes a digital camera that provides feedback data to the image computational device.

Abstract: A multi-layer image display system and method thereof, in which liquid crystal type image display units for displaying the images according to depth necessary for obtaining the stereoscopic image are arranged according to layers at a predetermined interval without overlapping each other along the rotary axis and rotated as displayed the layer image corresponding to each image display unit, by which the screen is on to express the stereoscopic image when each image display unit arrives at the user's position; and another method in which the reflector or half mirror is installed instead of the image display unit and the layer image corresponding to the relative depth of the reflector or half mirror is synchronized with the rotation speed to express the stereoscopic image in the fixed high speed display device.

Abstract: A self-illuminating video screen system employing a concave display surface which provides for enhanced depth cueing. A method of designing a variety of shapes of self-illuminating video screen display surfaces by varying certain parameters of a common master equation. Self-illuminating video screen systems having display surface shapes providing optimum viewing for specific applications.

Abstract: A substantially monocentric arrangement of optical components provides stereoscopic display of a real image, electronically scanned by resonant actuation of a resonant fiber scanner (137) using a flexible optical waveguide and projected toward a curved retro-reflective surface (124). To form each left and right intermediate image component, separate left and right image generation systems (70) each comprise a resonant fiber scanner (137) that itself comprises a resonant cantilever portion (139) of optical fiber (138) that directs a modulated beam in a curved pattern for projection, such as by a ball lens assembly (30). A monocentric arrangement of optical components images the left and right ball lens pupil at the corresponding left and right viewing pupil (14) of the observer (12) and essentially provides a single center of curvature for projection components. Use of such a monocentric arrangement provides an exceptionally wide field of view with large viewing pupils (14).

Abstract: A projection system for projecting a stereographic image onto a viewing surface is provided, the stereographic image including a left-eye image and a right-eye image. The projection system includes a light source for producing a beam, a beam splitter for splitting the beam of light into a right image beam and a left image beam, an image engine for producing the stereographic image, and a projection lens. The image engine includes a left optical path for producing the left-eye image from the left image beam, the left optical path including an upstream left polarizer, a left image-producing element and a downstream left polarizer, and a right optical path configured to produce the right-eye image from the right image beam, the right optical path including an upstream right polarizer, a right image-producing element and a downstream right polarizer.

Abstract: An apparatus and method for generating and projecting autostereoscopic images with a look around feature, in particular a device which creates several full resolution perspective views of a scene and makes each one visible within a different region of space in front of a special lens screen assembly on which the images are projected. The apparatus, including an illumination system, a light valve, a relay lens, a beam steering device, a plurality of projection lenses and mirrors, a focusing lens, and a screen assembly such that the mirrors focus light exiting the projection lenses and the screen assembly has a diffuser.

Abstract: A system and method for enhancing the realism of a displayed image may include an image display subsystem and a shadow projector. When an image is displayed, a shadow is projected near the image so that the shadow appears to be cast by the image. Shadows and lighting effects may also be reflected within a displayed image by rendering shadows and lighting corresponding to the viewer's environment within the image before or during display.

Abstract: An improved real image projection device includes a real image projection system for projecting a real image from one or more sources that transmit, reflect or emit light, and an e-mail capture system that includes a computer, microprocessor device, memory, or other device for storing an e-mail database, and a keyboard, touch-screen device, or pointing device and display monitor, or other input device, arranged for a viewer of the real image to enter one or more e-mail addresses into the database.

Abstract: A real image projection system comprising two or more optical surfaces of revolution, with at least one comprising an aspheric surface of revolution. The aspheric surface of revolution is of a design to reduce natural aberrations inherent in imaging using surface of revolutions of the conic family of curves.

Abstract: An image projector, having a light source, an LCD panel into which a light emitted from the light source enters, and a projection lens into which the light emitted from the LCD panel enters. There exists, in an entrance pupil of the projection lens, a range in which light emitted from respective pixels of the LCD panel overlap with each other at least in a horizontal direction. The image projector forms part of an image display.

Abstract: For providing the image projecting system capable of substantially superimposing images without image blur which are provided from a plurality of image projecting apparatus when the original images are superimposed using the plurality of image projecting apparatus, distortion value of distortion aberration of images from projecting optical system comprised in the image projecting system is made substantially coincided in a region of using image height.

Abstract: An image projecting apparatus is provided to project a real image of an object to be displayed while obscuring the object from view by an observer located exteriorly of the image projecting apparatus. The apparatus includes a housing (12) having an interior and a view area (14) for the real image. First and second reflective surfaces (40, 50), such as mirrors, are disposed in the housing. The first reflective surf (40) must be concave of a variety of geometric shapes. The second reflective surface (50) may be concave or, alternatively, planar. A masking member is interposed between the object and the view area. The second reflective surface can define the masking member. The first and second reflective surfaces are arranged at an acute angle to each other.

Abstract: Apparatus for displaying an image suspended in space comprises an object (1) for display, a retroreflector (2) receiving light from the object, a beamsplitter (3) in a path for light from the object to the retroreflector, and a concave mirror (4) between the beamsplitter and the retroreflector. The beamsplitter makes an oblique angle to the direction (6) of propagation of the light such that it transmits some light. Light from the beamsplitter is reflected by the mirror to the retroreflector which reflects it back via the mirror to the beamsplitter. This retroreflected light is reflected by the beamsplitter to form a real image (5) suspended in space. The use of a concave mirror improves viewability over apparatus including a converging lens because unwanted reflections from the surfaces of the lens are eliminated.

Abstract: A head up display system is disclosed that includes a housing, an aspheric reflector, and a modular projection unit. The modular projection unit includes a backlight, a spherical reflector, an infrared mirror, one or more display devices, and cooling apparatus. The backlight has a spherical reflector with inner and outer reflective spherical surfaces and a central opening that is used to recycle light and provide a desired aperture shape. The one or more display devices may be liquid crystal displays, such as active matrix liquid crystal displays. Exemplary cooling apparatus includes an air inlet, a fan and an air outlet that forces air past heat generating components of the projection unit.

Abstract: The invention features a volumetric display system including an optical relay, a motor, a support structure coupled to the motor, a projection screen disposed on the support structure, and a projection optic. During operation, the projection optic receives a light beam from the optical relay and projects the light beam onto the projection screen. Also, the motor rotates the support structure, the projection screen, and the projection optic about a rotation axis.