Thomas J. Haven

Bio: Thomas J. Haven is an academic researcher from Delta Electronics. The author has contributed to research in topics: Polarization (waves) & Primary color. The author has an hindex of 4, co-authored 4 publications receiving 148 citations.

Polarization recapture system for liquid crystal-based data projectors

Abstract: A projection display system includes a light source emitting a randomly polarized light and a polarization recapture system including a tunnel integrator and a transmitting/reflecting polarizer coupled to the output end of the tunnel integrator. The input end of the tunnel integrator includes an input aperture and a reflective inside surface coated with a quarter wave retarder. In operation, the randomly polarized light enters the tunnel integrator through the input aperture. The polarization recapture system transmits light having a first polarization as polarized light output and recycles light having a second polarization orthogonal to the first polarization. The light having the second polarization is reflected by the transmitting/reflecting polarizer back into the tunnel integrator. The polarization recapture system recycles the light having the second polarization by reflecting and reorienting the light having the second polarization to light of the first polarization.

Illumination system for a projection system

Abstract: An illumination system for illuminating an object includes a light source and a lens array system. The light source includes an illumination element emitting light rays and surrounded by a parabolic reflector. The lens array system includes a first lens array plate and a second lens array plate. The first lens array plate includes a matrix of lenslets where, in one embodiment, each lenslet has a shape matching the aspect ratio of the object to be illuminated. The second lens array plate includes a radial pattern of wedge shaped lenslets each corresponding to a lenslet in the first lens array plate. Each wedge shaped lenslet in the second lens array plate has dimensions that are selected to provide a radial and theta collection angles matching the maximum divergence angle of the light source and the maximum divergence angles of the corresponding lenslet in the first lens array plate.

Full color rear screen projection system using a single monochrome TFT LCD panel

Abstract: A rear screen projection system uses a single monochrome liquid crystal display (LCD) panel for displaying full color images In one embodiment, an apparatus for projecting an image includes an illumination source generating polarized light beams in three different primary colors, a monochrome liquid crystal display panel including a two-dimensional array of addressable pixels, the array of addressable pixels is divided into multiple image areas, and a projection lens assembly for aligning and projecting the images generated by the multiple image areas of the liquid crystal display panel to form a full color image In one embodiment, the illumination source includes a light source emitting randomly polarized white light, a polarizing element coupled to receive the randomly polarized white light and generate a polarized white light beam, and color separating elements for separating the polarized white light beam into the polarized light beams in three different primary colors

Dual lamp illumination system using multiple integrator rods

Abstract: An illumination system includes a first light source, a second light source, a first light integrating device and a second light integrating device. Each light integrating device includes an input aperture at an input end for receiving input light and a turning mirror at an output end for reflecting light onto an output aperture where the output aperture is positioned in a direction perpendicular to the input aperture. The illumination system further includes a first reflective mirror and a second reflective mirror each coupled to direct light from the respective light source into the input aperture of the respective light integrating device. The illumination system includes a third light integrating device including an input aperture optically coupled to the output apertures of the first and second light integrating devices. The input aperture of the third light integrating device receives light collected by the first and second light integrating devices.

Self-contained interactive video display system

Abstract: A self-contained interactive video display system. A projector projects a visual image onto a screen for displaying the visual image, wherein the projector projects the visual image onto a back side of the screen for presentation to a user on a front side of the screen. An illuminator illuminates an object near the front side of the screen. A camera detects interaction of an illuminated object with the visual image, wherein the screen is at least partially transparent to light detectable to the camera, allowing the camera to detect the illuminated object through the screen. A computer system directs the projector to change the visual image in response to the interaction.

Interactive directed light/sound system

Abstract: An interactive directed beam system is provided. In one implementation, the system includes a projector, a computer and a camera. The camera is configured to view and capture information in an interactive area. The captured information may take various forms, such as, an image and/or audio data. The captured information is based on actions taken by an object, such as, a person within the interactive area. Such actions include, for example, natural movements of the person and interactions between the person and an image projected by the projector. The captured information from the camera is then sent to the computer for processing. The computer performs one or more processes to extract certain information, such as, the relative location of the person within the interactive area for use in controlling the projector. Based on the results generated by the processes, the computer directs the projector to adjust the projected image accordingly. The projected image can move anywhere within the confines of the interactive area.

Computer vision based touch screen

Abstract: A self-contained interactive video display system. A projector projects a visual image onto a screen for displaying the visual image, wherein the projector projects the visual image onto a back side of the screen for presentation to a user on a front side of the screen. An illuminator illuminates an object near the front side of the screen. A camera detects interaction of an illuminated object with the visual image, wherein the screen is at least partially transparent to light detectable to the camera, allowing the camera to detect the illuminated object through the screen. A computer system directs the projector to change the visual image in response to the interaction.

Interactive video window

Abstract: An interactive video window display system. A projector projects a visual image. A screen displays the visual image, wherein the projector projects the visual image onto a back side of the screen for presentation to a user on a front side of the screen, and wherein the screen is adjacent to a window. An illuminator illuminates an object on a front side of the window. A camera detects interaction of an illuminated object with the visual image, wherein the screen is at least partially transparent to light detectable by the camera, allowing the camera to detect the illuminated object through the screen. A computer system directs the projector to change the visual image in response to the interaction. The projector, the camera, the illuminator, and the computer system are located on the same side of the window.

Processing of Gesture-Based User Interactions

Abstract: Systems and methods for processing gesture-based user interactions with an interactive display.