Abstract: In accordance with various exemplary embodiments, solar energy shade structures and methods of design and revenue generation are disclosed. These systems comprise structures capable of supporting solar panel at heights greater than 18 feet above their mounting surface. These systems may be installed in confined spaces. These systems also comprise structures that are customizable, allowing an installation to be configured with a desired lighting and environmental effect. The methods discussed herein describe processes for achieving desired design effects based on natural elements. Moreover, the methods discussed herein describe processes for reducing the costs of generating solar energy and/or reducing the costs of providing a solar structure.

Abstract: Non-imaging radiation collecting and concentrating devices, and assemblies, are disclosed. The non-imaging radiation collecting and concentrating devices comprise an entrance aperture for receiving incoming radiation, an exit aperture located opposite to the entrance aperture for outputting concentrated radiation, and one or more concaved reflectors arranged between the entrance and exit apertures. The concaved reflectors define an acceptance angle of the device relative to an optical axis thereof and configured such that their optical focuses are located between edges of the exit aperture and the optical axis, thereby substantially preventing escape of the incoming radiation received in the entrance aperture within the acceptance angle and providing substantial uniform radiation collection at the exit aperture of the device.

Abstract: The invention provides an imaging system comprising an optical element for deflecting axially incident light into a series of axially spaced outward radial projections, and further comprising an image collection means for collecting reflected light. The element comprises a plurality of light deflecting surfaces or features which are arranged at axially successive points along the element, each at a different radial location. The light-deflecting surfaces are arranged to deflect light incident upon them from an axial direction in a radial direction, each thereby generating a radial projection of light from the element. A beam or beam bundle projected along the element has successive outer annular layers stripped by the facets and deflected outwards at different axial points along the structure.

Abstract: An electromagnetic radiation collecting device is presented, which is particularly useful for the collection of solar radiation, providing optimal radiation collection throughout the daytime, and throughout yearly seasonal changes. The collector entails a redundant number of static collectors arranged in such a manner as to provide maximal and chronologically evened collection outline.

Abstract: A display apparatus including a display panel and a light source module is provided. The display panel displays an image frame according to a light beam. The light source module provides the light beam to the display panel. The light source module includes a light emitting device, a lens module, a reflection device, and a light emitting surface. The light emitting device provides the light beam. The lens module is disposed in a transmission path of the light beam and adjusts the light beam to be focused or dispersed. The reflection device receives the light beam passing from the lens module and reflects the light beam to the light emitting surface. The lens module includes a lens disposed in the transmission path of the light beam and moves relative to the light emitting device to adjust a viewing angle of the light emitting surface.

Abstract: In some embodiments, optical systems with a reflector and a lens proximate a light output opening of the reflector provide light output with high spatial uniformity and high efficiency. The reflectors are shaped to provide substantially angularly uniform light output and the lens is configured to transform this angularly uniform light output into spatially uniform light output. The light output may be directed into a light modulator, which modulates the light to project an image.

Abstract: Systems, methods, and apparatus by which solar energy may be collected to provide electricity, heat, or a combination of electricity and heat are disclosed herein.

Abstract: A solar module riser assembly that is configured to allow a solar module attached thereto to fall-to-flat when not being forced into an angular position is provided. A riser assembly includes a riser support and a tube support attached to the riser support. A torque tube may extend across a plurality of riser assemblies and be retained by tube supports attached to each of the riser assemblies. A torque tube support is configured to rotate about the riser support and thereby position a solar module coupled thereto at an optimum angular orientation for solar exposure and track the sun. A first riser and second riser may be configured on opposing sides of a central drive device and lever arms attached to link bars drive tube supports when the link bar is moved. The first and second riser may be configured to create equal and opposite force on the link bar.

Abstract: An electromagnetic radiation collection apparatus includes an exterior including a bottom portion and first and second walls extending from the bottom portion, the exterior defining a cavity in the bottom portion, the cavity being configured to receive a thermally absorbing material; and a radiation collector. The radiation collector includes a first surface on an interior of the first wall, the first surface being at least partially reflective and positioned to reflect radiation that is incident on the first surface into the cavity; and a second surface on an interior of the second wall, the second surface being at least partially reflective and positioned to reflect radiation that is incident on the second surface into the cavity, where the first and second surfaces face each other to at least partially define an interior region of the radiation collector, and the cavity defines an opening to the interior of the radiation collector.

Abstract: The invention relates to a prestressed solar collector module forming a support structure for solar collectors, of the type formed by a lattice bar structure including a central beam (1) essentially characterized in that: the central beam or torque box (1) takes the form of a multi-face polyhedron or cylinder, that is divided into sections (3) each section (3) being formed by multiple bent or curved plates (4), a surrounding triangular lattice structure (16) is provided to support the parabolic reflector (17) which structure is formed with L-shaped elements, all of the connections being formed with rivets, and all of the structure is prestressed using a series of tension rods (13, 14, 15) which optimize the flexural behavior of the structure and which include end anchoring points and intermediate through-points allowing the necessary curvature to be obtained and the tension to be maintained.

Abstract: Inflatable, flexible, collapsible, linear solar concentrator and heliostat designs, made primarily of flexible and elastic sheets enclosing and separating air-tight chambers which are elongated along and parallel to a main axis, with the chambers pressurized to different pressures form a structure and control the focus and rotation of a mirror.

Abstract: A solar concentrator comprises a pair of concentric reflectors having a spindle toroid geometry for focusing the collected solar radiation into a ring-shaped focal area, as opposed to the “point” or “line” focus of prior art configurations. In a preferred embodiment, each reflector is formed of a plurality of curved petals that are disposed in a contiguous, keystone arrangement that requires no additional fixturing to hold the petals in place. Such an arrangement reduces the weight, complexity and cost of the final solar concentrator structure.

Abstract: Inflatable, flexible, collapsible, linear solar concentrator and heliostat designs, made primarily of flexible and elastic sheets enclosing and separating air-tight chambers which are elongated along and parallel to a main axis, with the chambers pressurized to different pressures form a structure and control the focus and rotation of a mirror.

Abstract: Generally, the present disclosure provides a light duct bend used in a mirror-lined light duct system. In one aspect, the light duct bend includes an input region having a first propagation direction, an output region having a second propagation direction disposed at a bend angle to the first propagation direction, and a transition region connecting the input region to the output region. The transition region includes a plurality of vanes that subdivide the duct into channels, which can reduce the loss and/or disruption of collimation about one or more bends in the light duct system.

Abstract: Optical system for a telescope having independent optical arms adapted to collect light rays over a first cross sectional area and compress it into a second cross sectional area less than the first cross sectional area. Orthogonal mirror pairs of parabolic trough mirrors compress light in first one dimension and then the other dimension and feed the light into a focusing smaller telescope structure. The gathered light is kept parallel and its wavefront is kept in phase, allowing the telescope to have the diffraction limit of the collective aperture. The optical arms are independently adjustable to point the system toward different objects of interest and track them.

Abstract: A solar collector has operably connected reflective panels that can be positioned to substantially form a parabolic trough that concentrates solar radiation onto a tube running along the focal line of the trough. A folding mechanism can be manually or automatically operated to selectively fold and unfold the panels into open and closed positions and into any number of intermediate positions, including the position characterized by formation of a parabolic trough. A rotating mechanism can be manually or automatically operated to selectively rotate the solar collector about an axis parallel to the focus line of the parabolic trough.

Abstract: An exposure apparatus includes a first optical unit configured to condense light from a light source, a catoptric integrator configured to form plural secondary light sources using light from the first optical unit, the catoptric integrator including plural cylindrical reflection surfaces having the same generatrix direction, an aperture stop arranged perpendicular to the generatrix direction, and a second optical unit configured to superpose light from each secondary light source onto an illumination surface, wherein the catoptric integrator includes plural integrator parts each having plural cylindrical reflection surfaces, and the plural integrator parts are arranged in a direction perpendicular to the generatrix direction and to an arrangement direction of the cylindrical reflection surfaces and located at an incident side of the aperture stop.

Abstract: A solar energy concentrator system includes a supporting structure and a plurality of solar modules coupled to the supporting structure. Each module of the plurality of solar modules includes a plurality of Fresnel reflectors. The plurality of reflectors is arranged to focus solar radiation linearly onto a photovoltaic cell providing two axis concentration. The supporting structure is rotatably connected to a plurality of support members and aligned to allow the supporting structure to rotate about a polar axis. A plurality of optical trusses is connected to the plurality of solar modules and rotatably connected to the supporting structure to allow the plurality of solar modules to be rotated about a declination axis to track a motion of the sun through seasons of the year.

Abstract: A radiant energy flux transformation system including a primary linear focus concentrating collector formed by a plurality of cylindrical slat-like reflectors and a secondary elongated collector is described. The reflectors of primary collector generally have concave or planar transversal profiles and are positioned in a stepped arrangement with longitudinal axes being parallel to each other and to the secondary collector. The reflectors are tilted away from the direction to the source of radiant energy at a range of angles being less than 45° to reflect and direct the incident energy flux to a common focal region located below the primary collector where the concentrated flux is intercepted and further transformed by the secondary collector. In addition to efficient concentrating radiant energy such as sunlight, the system can provide uniformity or a desired energy distribution in the concentrated flux.

Abstract: The present invention provides a reflector having a light-diffusing property which suppresses inter-object reflection over a wide angle, and giving particularly high reflectance in an intended range of viewing angle; and to provide a reflection type liquid crystal display device using the same. The reflector includes a plurality of light-reflective concave portions. Each of the concave portions is formed so that an inclination angle (an angle between a plane tangential to a point on a concave surface and the surface of the base material) is maximum on a side portion of the curved surface, and so that the direction of the side portion having the maximum inclination angle is on a far side from a view point of an observer.

Abstract: An ultracompact, lightweight, reflective telescope is described which has no loss due to central obscuration for a beam being projected from its focus. The optical surfaces are composed of matched conics of rotation.

Abstract: The optical deflector includes the electro-optical element to deflect light by utilizing its refractive index variation, and it also includes a reflective adjustable optical deflector element with a reflective element to reflect the deflected light. This arrangement provides down-sized optical devices, such as variable optical attenuators, optical shutters, and optical switches, with high response speed and low insertion loss.

Abstract: This optical assembly comprises a securing support (40), an optical focusing element (44) and a reflecting mirror (42) which is suitable for reflecting an incident light beam (F1) towards the optical focusing element (44) in order to focus it onto an illumination plane (P). The reflecting mirror (42) is movable relative to the securing support (40). The optical focusing element (44) is movable relative to the securing support (40). The assembly includes elements for connecting the focusing element (44) to the mirror (42) for synchronised displacement of the two of them. The assembly is useful in devices for illuminating operating fields.

Abstract: A light condenser suitable for EUV lithography that includes reflective rings concentric to an optical axis. Each ring has a reflective surface to reflect light rays emanating from a light source so that the light rays converge towards a mask to produce Köhler illumination on the mask. The reflective surface has a curve segment that includes a section of a parabolic curve that is rotated relative to an optical axis and has a focal point at the light source.

Abstract: A technique for changing the cross-sectional profile of a beam of light from, for example, circular or elliptical to thin involves dividing the beam of light into cross-sectional portions, rotating the cross-sectional portions, and then concatenating the rotated cross-sectional portions to form a thin beam. The resulting thin beam has a long dimension that is formed by the concatenation of the cross-sectional portions of the original beam. A device for changing the cross-sectional profile of a beam of light may be fabricated with silicon optical bench technologies or other molding technologies. The device includes facets that divide a beam of light into cross-sectional portions, rotate the cross-sectional portions, and then concatenate the rotated cross-sectional portions to form a thin beam.

Abstract: A radiant energy collecting and converting device having at least one array of slat-like concave reflective elements and an elongated receiver. The device efficiently concentrates and converts radiant energy, such as sunlight, to other useful types of energy, such as electricity and heat. The mirrored surfaces of reflective elements having appropriate individual profiles represented by curved and/or straight lines are positioned so that the energy portions reflected from individual surfaces are directed, focused, and superimposed on one another to cooperatively form a common focal region on the receiver. The mirrored surfaces are inclined towards one another at their rear ends facing the receiver and can be arranged to provide lens-like operation of the array. The receiver can be arranged in line photovoltaic cells or a tubular solar heat absorber.

Abstract: The disclosure is a radiation collecting/emitting device to/from different spatial directions, the apparatus in the preferred design is manufactured in a single piece and the work surface is modified to obtain a reflective surface for the radiations of interest. In an alternate design, the device is covered by an envelope or bell to increase the effectiveness of the device and protect it from the surrounding environment. The device can be used in a wide variety of applications, such as solar energy collection for industrial or commercial purposes, diverse electromagnetic radiations antennae or radar, since its area of action is 360° related to the horizontal and 180° related to the vertical.

Abstract: The electromagnetic wave focusing device has a mirror group consisting of a focal-line type primary reflective mirror and secondary reflective mirror which have a unique parabolic cross-sectional shape. Incident light rays are primarily reflected by the primary reflective mirror and are then secondarily reflected by the secondary reflective mirror, so that solar rays are focused at one point. The electromagnetic wave focusing device can be made extremely thin and light-weight, and can be folded without causing great loss of precision or great increase in mass. Consequently, the mirror bodies can be folded into a compact form and loaded inside the restricted space of a rocket or the like; thus, the device can be transported into aerospace, and a sunlight focusing device having high focusing performance can be reproduced on-site with a high precision.

Abstract: An omnidirectional vision sensor includes: an optical system including a body-of-revolution mirror having a convex portion and having a symmetrical structure with respect to a revolution axis, wherein the body-of-revolution mirror includes a cutaway section in the convex portion of the body-of-revolution mirror so as to allow light incident from surroundings of the revolution axis of the body-of-revolution mirror to be collected; and imaging means, including a light-receiving element for receiving the collected light and image processing means for converting an optical image generated from the collected light received by the light-receiving element into image data. The revolution axis of the body-of-revolution mirror and an optic axis of the light-receiving element coincide.

Abstract: A soda inclusive glass substrate is coated with a highly tetrahedral amorphous carbon inclusive layer that is a form of diamond-like carbon (DLC). In certain embodiments, the amorphous carbon layer includes at least about 35% sp3 carbon-carbon bonds, more preferably at least about 70%, and most preferably at least about 80% of the sp3 carbon-carbon bonds. The high density (e.g. greater than or equal to about 2.4 gm/cm3) of the amorphous carbon layer prevents soda from exiting the glass and reacting with water at surface(s) of the glass, thereby minimizing visible stains (or corrosion) on the glass. The high density amorphous carbon layer also may repel water. In some embodiments, the highly tetrahedral amorphous carbon layer is part of a larger DLC coating, while in other embodiments the highly tetrahedral layer forms the entirety of a DLC coating on the substrate.

Abstract: A hollow tube having a pair of openings which have their respective different diameters and arm opposed each other is prepared. Then, a pulsed laser beam is introduced into the hollow tube from the larger opening thereof and then, reflected multiply on the inner wall surface of the hollow tube. The introduced pulsed laser beam is focused during the traveling for the smaller opening of the hollow tube to generate a focused laser beam. The thus obtained focused laser beam is output from the smaller opening of the hollow tube.

Abstract: A luminaire has two oppositely positioned rows with reflectors made of separate sectors. The individual reflectors are separated by edge portions, which are positioned transversely to the longitudinal axis of the luminaire and transversely to a light emission window. The edge portions are spaced apart by a distance D, measured transversely to the longitudinal axis, of between 1 and 2 times the diameter of an associated lamp.

Abstract: A Low loss resonator is provided, which consist of two confocal parabolic reflectors and two flat reflectors forming a closed cavity capable of direct to the output window, stimulated emissions generated in the axes parallels to the axis of symmetry and the radial axes, being the point of origin of the radial axes the common focal point of the parabolic reflectors. The Low loss resonator has the advantage of extract energy from the active medium more efficiently than cylindrical shaped resonators.

Abstract: An improved mirror assembly comprises a combination of mirrors at the front corners of the vehicle along with a pair of side mirrors and a mirror at the back of the vehicle. The mirrors are so positioned to eliminate any blind spots along the boundaries of the vehicle while enhancing the lines of sight therealong, particularly for objects along the front and rear of the vehicle. The mirrors associated with these latter zones are positioned so as to be adjacent the driver to preclude obstruction by packages stacked in the vehicle.

Abstract: A parabolic reflector assembly (10) comprising a base member (11) formed of magnetic material and defining a parabolic surface (12), and a flexible magnet sheet (18) carrying a reflective sheet (19) magnetically bonded to the parabolic surface to form a parabolic reflecting surface. A method of manufacturing the parabolic reflector assembly is also disclosed. The parabolic reflect or assembly typically may be used as a concentrator is solar energy concentrating apparatus.

Abstract: A panoptic camera system that can be used to capture all the light from a hemisphere viewing angle is disclosed. The panoptic camera comprises a main reflecting mirror that reflects light from an entire hemisphere onto an image capture mechanism. The main reflecting mirror consists of a paraboloid shape with a dimple on an apex. The surface area around the dimple allows the main reflector to capture light from behind an image capture mechanism or a second reflector. When two panoptic camera systems that capture the light from an entire hemisphere are placed back to back, a camera system that “sees” light from all directions is created. A stereo vision panoramic camera system is also disclosed. The stereo vision panoramic camera system comprises two panoramic camera systems that are separated by a known distance. The two panoramic camera systems are each placed in a “blind spot” of the other panoramic camera system.

Abstract: A faceted reflector assembly including a plurality of reflector segments which are preferably, but not necessarily, comprised of pre-anodized and enhanced aluminum having a specular, semi-specular or a diffuse finish. The reflector segments include interlocking means such as tabs and slots for attachment to other reflector segments. The reflector segments, when interlocked, form the faceted reflector of the present invention.

Abstract: The invention relates to a reflector having reflection surface with facets for reflecting light beams and for generating a light field with a hollow basic element which presents a first end for accommodating an illuminant (mounting end), as well as a second end which represents a light outlet aperture, whereby for generating a specific light field contour with a given form of illuminant the forms of individual facets and their position relative to the optical axis of the reflector are selected specifically.

Abstract: The present invention is a display apparatus that provides protection against damage for a metallic layer. The display apparatus includes a light modulating layer, a polarizer, and a light directing film. The light directing film includes a prismatic structure having two sides, where one side includes saw tooth formations having tilted surfaces and a metal layer on the side of the prismatic substrate having the saw-tooth formations. A tilt angle of the tilted surfaces offsets an optimal viewing angle for the display from a glare angle for the display. In a first embodiment of the invention, the light directing film of the display apparatus further includes an inorganic protective layer formed on the metal layer, wherein the inorganic protective layer inhibits molecular transfer to the metal layer and balances the color of reflected and transmitted light. The light directing film further includes a pressure sensitive adhesive layer between a polarizer and the inorganic protective layer.

Abstract: A safety mirror lens assembly includes a mirror unit with a mirror lens that has a three-dimensional convex/ellipsoid reflective surface which terminates in an oval shape peripheral edge. The reflective surface is such that a notional line traced to coincides with the major axis has a first constant radius of curvature and a second notional line traced to coincide with the minor axis has a second constant radius of curvature. The first radius of curvature is substantially greater than the second radius of curvature. The mirror lens is usable for a cross-over mirror for a vehicle, for example, a school bus.

Abstract: The present invention is a display apparatus that provides protection against damage for a metallic layer. The display apparatus includes a light modulating layer, a polarizer, and a light directing film. The light directing film includes a prismatic structure having two sides, where one side includes saw tooth formations having tilted surfaces and a metal layer on the side of the prismatic substrate having the saw-tooth formations. A tilt angle of the tilted surfaces offsets an optimal viewing angle for the display from a glare angle for the display. In a first embodiment of the invention, the light directing film of the display apparatus further includes an inorganic protective layer formed on the metal layer, wherein the inorganic protective layer inhibits molecular transfer to the metal layer and balances the color of reflected and transmitted light. The light directing film further includes a pressure sensitive adhesive layer between a polarizer and the inorganic protective layer.

Abstract: An optical integrator comprising a two dimensional array of mirror segments formed from an off-axis section of a parent parabolic surface. The mirror segments are arranged so that the focus of each mirror segment is in a plane. Incident collimated radiation is coaxial with the system axis. The secondary point source images are substantially aberration free.

Abstract: A safety mirror lens assembly includes a mirror unit with a mirror lens that has a three-dimensional convex/ellipsoid reflective surface which terminates in an oval shape peripheral edge. The reflective surface is such that a notional line traced to coincides with the major axis has a first constant radius of curvature and a second notional line traced to coincide with the minor axis has a second constant radius of curvature. The first radius of curvature is substantially greater than the second radius of curvature. The mirror lens is usable for a cross-over mirror for a vehicle, for example, a school bus.

Abstract: A method of reversing a laser beam in a machine includes orienting a pair of reflective surfaces at an angle of approximately 90° relative to each other. The laser beam is directed in a first direction such that the laser beam sequentially impinges upon a first of the reflective surfaces reflects off of the first reflective surface, impinges upon a second of the reflective surfaces, and reflects off of the second reflective surface in a second direction substantially parallel to and opposite the first direction. A pivot axis is substantially parallel to each of the reflective surfaces. Each of the reflective surfaces is pivoted about the pivot axis by a substantially equal angle to thereby change a position of the laser beam after reflecting off of the second reflective surface.

Abstract: A condenser for use with a ring-field deep ultraviolet or extreme ultraviolet lithography system. A condenser includes a ripple-plate mirror which is illuminated by a collimated beam at grazing incidence. The ripple plate comprises a plate mirror into which is formed a series of channels along an axis of the mirror to produce a series of concave surfaces in an undulating pattern. Light incident along the channels of the mirror is reflected onto a series of cones. The distribution of slopes on the ripple plate leads to a distribution of angles of reflection of the incident beam. This distribution has the form of an arc, with the extremes of the arc given by the greatest slope in the ripple plate. An imaging mirror focuses this distribution to a ring-field arc at the mask plane.

Abstract: An irradiance redistribution guide (IRG) for providing from a radiation source having a nonuniform irradiation distribution, a predetermined irradiance distribution over a predetermined target area spaced away from the IRG, includes a tubular reflective inner surface disposed between an entrance aperture and an exit aperture. The reflective inner surface has a varying cross-sectional radius. The profile of the cross-sectional radius is defined by a spline function that is uniquely determined by a plurality of knots. The IRG, when used in conjunction with a high-power solar concentrator, is advantageous in materials processing that requires high irradiance level that is uniformly distributed over an area spaced away from the exit aperture by a working distance.

Abstract: A fundamental surface for a reflection surface of a reflection mirror of a vehicle lamp is formed in a manner such that a curved surface where an insertion hole, through which a light source is inserted into the reflection mirror in the direction oblique to the optical axis of the reflection mirror, is to be formed, is made smoothly continuous to the remaining curved surface without any level-difference. A group consisting of a number of paraboloids of revolution with different focal distances are put on the fundamental surface, and a group of closed curves formed as intersecting lines of the fundamental surface and the group of paraboloids of revolution are determined. A number of reflection steps in the form of loop are formed on the reflection surface. The reflection steps between the adjacent ones of the closed curves are defined by portions of the paraboloid of revolution between the adjacent ones.

Abstract: In a reflection type angle of view transforming optical apparatus for transforming an angle of view in an image apparatus and so forth, sufficient strength can be provided and process is facilitated by using reflecting mirrors in a wide angle optical system. The reflection type angle of view transforming optical apparatus includes a primary mirror 8 having a reflecting surface provided in an axisymmetric form to reflect incident light 12 as primary reflected light 13, a secondary mirror 10 having a reflecting surface provided in an axisymmetric form about the same axis of rotational symmetry 9 as that of the primary mirror 8, opposed to the primary mirror 8 so as to reflect the primary reflected light 13 and to get secondary reflected light 14 for focusing on a view point, and a transparent case 11 to support the primary mirror 8 and the secondary mirror 10, and transmit the incident light 12.

Abstract: The line bow phenomenon is reduced by appropriately setting the reflective surface and/or the external shape of an optical element (e.g., a toric mirror) thereby realizing approximately linear illumination of the surface of the original document that is being read. In order to do this, optical elements can be formed so that the external shape of the reflective surface of the optical element is bow-shaped. Alternatively, the optical element can be arranged so that the optical axis of the reflective surface is parallel to the axis of the light reflected from the reflective surface.

Abstract: A head-mounted image display apparatus (HMD) including an ocular optical system, which has an F-number of 1.5 to 3 and enables a flat and clear image to be observed at a view angle of up to 60.degree. or more with substantially no aberration. The HMD has at least two, surfaces and each having a concave surface directed toward the pupil. The two surfaces are disposed so that light rays from an image display device are reflected by the first surface, and the reflected light rays are reflected by the second surface and pass through the first surface to enter an observer's eyeball.