Abstract: The collector/concentrator includes a primary concave reflector (1) supported on a base body (3) obtained by injection moulding, which defines a central support (5) supporting a region around a central opening (6) of the primary reflector (1), a plurality of peripheral legs (7) supporting respective peripheral regions of the primary reflector (1) and first integral connection members (8) connecting said peripheral legs (7) with the central support (5). The peripheral legs (7) have bottom ends (7a) leaning on a substantially flat supporting surface and top ends (7b) located above the peripheral regions of the primary reflector (1) that are in contact with a substantially flat transparent panel (15) supporting a secondary convex reflector (2) that concentrates the solar radiation reflected by the primary reflector (1) towards a receiver unit (18) through the central opening (6).

Abstract: A described embodiment provides a technology for concentrating or focusing electromagnetic energy to an arbitrary desired spatial distribution, utilizing a rotatable base, a plurality of mirrors mounted to the rotatable base, and an optical receiver that is moveable in an azimuth path relative to the plurality of mirrors. A described embodiment can comprise a driver for rotating the base and a adjusting linkage that connects the plurality of mirrors so that they track in a coordinated fashion. Another embodiment comprises an optical positioning assembly on which each mirror is mounted. An optical positioning assembly adjusts each mirror to the sun's altitude and the location for the optical receiver. This assembly is connected to the adjusting linkage so that a single driver can move all the mirrors if desired.

Abstract: A mirror arrangement for a laser processing system includes a mirror configured to deflect laser radiation incident on the mirror arrangement onto a workpiece. The mirror arrangement includes first, second, and third mirror regions. A surface of the third mirror region is parallel to or recessed from a direction of propagation of the laser radiation incident on the mirror arrangement such that the third mirror region forms a shadow zone.

Abstract: A light-collecting device and a light-collecting method thereof are disclosed, capable of providing a simple combination structure, guiding light beams to be almost perpendicularly entered into a receiving element, and increasing the absorption efficiency of a light-receiving element. The light-collecting device includes a light concentrator and a light collector provided with total internal reflection and assembled with a light-receiving element. The light collector is defined with a light-entering aperture disposed near or located at a focusing region of the light concentrator and a light-radiating aperture.

Abstract: A reflector-concentrator unit including a sandwich structure with an upper lamina, a lower lamina, a filler layer between both, and a frame. The upper lamina has associated therewith an outer reflective surface to reflect incident rays and to concentrate them in a linear focus. The material of the filler layer is adhered to the upper and lower laminas of the sandwich structure and to the frame and is rigid enough to precisely assure a predetermined stable operating position of the upper lamina in relation to the frame. The frame includes positioning configurations usable to precisely position the reflector-concentrator unit and the associated reflective surface in relation to an external element of an installation.

Abstract: A reflector to reflect solar radiation, the reflector having a concave reflector surface, wherein the surface curves about a first axis and a second axis, the second axis being in a plane generally normal to the first axis and curved about the first axis. Also disclosed is an apparatus for collection and utilization of solar energy including at least one of the reflectors, and at least one photovoltaic cell associated with each surface and positioned relative to the associated surface so as to be positioned to receive radiation reflected by the associated surface and to convert the radiation to electrical energy. The apparatus further includes heat a conversion mechanism for converting excess solar radiation energy incident thereon to heat energy.

Abstract: The invention is directed to a system for concentrating light for solar thermal and solar photovoltaic generating systems. The system includes a plurality of concentrating regions. Each concentrating region includes an input end having a perimeter or width in a lenticular configuration, an output end having a perimeter or width in a lenticular configuration, and a portion located therebetween defined by a reflective boundary. The invention is also directed to a method of manufacturing a light collection system. The method includes forming a film having multiple recesses. Each recess includes an input end, an output end and a reflective boundary. The output end has a smaller perimeter or a width in a lenticular configuration than a perimeter or a width of the input end in the lenticular configuration.

Abstract: Disclosed is a light-collecting heliostat using flat mirrors of enhanced light-collecting efficiency. The gradients of low-price flat mirrors are adjusted when reflecting sunlight by the heliostat equipped with the flat mirrors, thereby causing reflection focal points having the same size as each of the mirrors to overlap, in the same number as the number of the reflective plates constituting the heliostat, on a heat collecting unit of collecting lights, so that a high temperature light-collecting focal point with a uniform temperature distribution is obtained.

Abstract: A heliostat system includes a base member adapted to be secured to a fixed surface, a transitional member that is formed as a substantially unitary member and a mirror member. The transitional member is coupled to the base member and to the mirror member. The mirror member includes a support portion coupled to the transitional member and a mirror portion. A first bearing coupling the base member and the transitional member provides relative changes in azimuth between the base member and the transitional member. A second bearing coupling the transitional member and the mirror member provides relative changes in elevation between the transitional member and the mirror member. A drive system rotates the transitional member about the first bearing and the mirror member about the second bearing to change the azimuth and the elevation of the mirror member.

Abstract: It allows lifting the heliostat in the warehouse and placing it on the cart, and once it reaches the installation spot in the field, the lifting structure is used to lift the heliostat from the cart and place it on a previously installed pedestal. The structure formed by an upper arch and two lower bases, being the upper arch, comprised at the same time by a central, elongated and horizontal profile, which presents two lateral profiles on its ends, from which vertical plates start at the bottom, provided with a hole in the proximity of its lower ends, through which the upper arch (2) is linked to the lower bases through some fixing mechanism, having the lower bases a semicircular support adapted to receive one of the support arms of the heliostat.

Abstract: Embodiments of the present invention include structures and methods for enhancing illumination uniformity from solar concentrators. Certain embodiments may use features on a reflective layer to globally correct for deviation in reflective behavior from a desired shape. Local features such as facets on a reflective layer are formed such that the resulting illumination profile represents a superposition of multiple facets. Features may be formed on a back film to correct the reflectance of the back film. In some embodiments, features may be formed on a front film to correct a profile from refraction. In some embodiments the corrections are for line concentrators. Global and local correction techniques may be used together, and may be used on front film or reflective film(s) together or separately. Global and/or local correction may also be used in combination with other approaches, such as secondary optic receiver compensation.

Abstract: A solar concentration device includes a bracket, a light transmitting window, a light receiving surface and at least two condensing lenses. The condensing lenses are arranged on the bracket and around the light transmitting window. One surface of the condensing lens is a light transmitting plane, and the other surface comprises uniformly distributed refractive prisms, the refractive surfaces of which are in parallel with each other. Light beam refracted by each refractive prism is uniformly irradiated on the light receiving surface. The light receiving surface is disposed in parallel with the light transmitting window. The application of this concentration device can increase at least twice the condensed light intensity.

Abstract: An arrangement utilizes diffractive, reflective and/or refractive optical elements combined to intensify and homogenize electromagnetic energy, such as natural sunlight in the terrestrial environment, for purposes such as irradiating a target area with concentrated homogenized energy. A heat activated safety mechanism is also described.

Abstract: A quasi-parabolic reflector and method are provided for a solar concentrator which produces a unique radiation pattern which is less susceptible to surface defects, less sensitive to target distance irregularities, and having greater uniformity of intensity for PV applications in comparison to that produced by true parabolic reflectors. Cross-sections of the quasi-parabolic reflector include spaced reflective surfaces which have focal areas spaced one from the other about an axis of symmetry. A method for forming petals of a quasi-parabolic reflector includes stamping them into shape using a stamping apparatus with a higher radius of curvature than the finished petal and iteratively testing and stamping the petal until the petal passes or fails a quality and accuracy threshold.

Abstract: A system is presented for collecting and concentrating light from a moving light source (e.g. the Sun). The system comprises at least one anamorphic optical element, defining an optical axis and a projection region and having a predetermined effective aperture which defines primary and secondary axes. The effective aperture is configured for collection of optical radiation arriving from a predetermined solid collection angle defining a first range of angles with respect to a plane spanned by said optical and primary axes. The anamorphic optical element is configured such that light passing through said effective aperture within a predetermined first range of angles within said predetermined solid collection angle is concentrated onto at least a part of said projection region. At least one receiver aperture is defined by at least a part of said projection region.

Abstract: Apparatus and methods are provided for use with photovoltaic cells, light emitting devices and the like. Reflective regions are formed on a sheet of flexible, non-metallic sheet material. The sheet material is folded to at least partially define a finished shape. Supports complete and maintain the folded condition such that one or more truncated parabolic troughs are defined. Incident light may be received and concentrated, or emitted light concentrated and projected, by way of the troughs.

Abstract: A solar collector is formed as a compound arrangement of a multiple number of tapered, pyramidal-type structures. This forms an N-stage solar collector, each stage providing a degree of concentration and thus forming an arrangement that is smaller than a single stage collector (while achieving the same amplification factor). The stages are arranged in tandem along a common optical axis, with the output of the first stage becoming the input for the second stage, and so on. It was found that a reduced number of reflections is required, reducing the loss of the overall system.

Abstract: A light-guide solar concentrator that requires less precision to assemble and manufacture than some other two-layer solar concentrators has a light-condensing layer and an optical waveguide layer. The light-condensing layer includes a plurality of focusing elements for focusing incident sunlight and a plurality of corresponding collimating elements for collimating the light for output to the optical waveguide layer. The optical waveguide layer receives the collimated light and has a plurality of deflectors for redirecting the light for lateral transmission through the optical waveguide layer toward an exit surface. A secondary optic optically coupled to the exit surface can also be provided to redirect the light toward a light collection area where a solar energy collector can be placed to harvest the concentrated sunlight.

Abstract: A thin-sheet panel assembly, In one embodiment, a substantially rigid thin-sheet panel assembly having a non-rigid thin-sheet component includes the thin-sheet component which has selected plan area and shape, a backer having a plan shape and area substantially similar to the thin-sheet component, and plural riser elements of selected height and configuration each extending from the backer to distal ends connected to a reverse surface of the thin-sheet component, the riser elements being configured and disposed in an array which causes the assembly to have substantial rigidity in a selected direction in the thin-sheet component, and the thin-sheet panel assembly further includes a bar coupled to the backer and extending between at least one pair of adjacent riser elements of the plural riser elements.

Abstract: A light trapping optical cover employing an optically transparent layer with a plurality of light deflecting elements. The transparent layer is configured for an unimpeded light passage through its body and has a broad light input surface and an opposing broad light output surface. The light deflecting elements deflect light incident into the transparent layer at a sufficiently high bend angle with respect to a surface normal and direct the deflected light toward a light harvesting device adjacent to the light output surface. The deflected light is retained by means of at least TIR in the system formed by the optical cover and the light harvesting device which allows for longer light propagation paths through the photoabsorptive layer of the device and for an improved light absorption. The optical cover may further employ a focusing array of light collectors being pairwise associated with the respective light deflecting elements.

Abstract: An optical system having an optical waveguide for collecting light, a receiver for receiving the light, and redirecting optics for transferring the light from the optical waveguide to the receiver. The optical system can be used for concentrating light such as in solar applications. The optical system can also be used for diffusing light in illumination applications by replacing the receiver with a light source such that the light flows in the reverse of the concentration system.

Abstract: A tracking system for reflecting electromagnetic radiation from a source to a target area, having at least one reflecting surface or mirror mounted to a support that fixes the reflecting surface orientation to focus electromagnetic radiation on the target area when the reflecting surface is at a first location at a first predefined time. The system has a path with at least the first location and a second location. The reflecting surface is movable along the path to maintain focus on the target area. The reflecting surface may have an orientation with a fixed declination angle and fixed hour angle. The source may include a moving source such as the Sun.

Abstract: Support structure, comprising a supporting wall, advantageously with a substantially parabolic profile or suchlike, for solar plants of the concentration type, and able to support at least a thin and flexible reflection plate, able to reflect the sun's rays in order to concentrate them in correspondence with collectors to exploit the solar energy. The support structure comprises clamping elements movable with respect to the supporting wall, and able to clamp the reflection plate in cooperation with the supporting wall. The support structure comprises adjustment means constrained to the clamping elements and able to cooperate with relative elastic means constrained to the supporting wall. The elastic means are disposed and conformed with respect to the supporting wall so as to exert an action of traction on the adjustment means and on the clamping elements, so as to exert the desired action of deformation on the reflection plate.

Abstract: An object is to provide a solar ray lighting device which is capable of reducing the blocking and the shadowing of beams of light reflected by heliostats and which is capable of fixing firmly and stably a heavy and large-sized center reflector. In a beam-down type solar ray lighting device, at least three supporting blocks are assembled together to form a pyramidal shape. In addition, an outer circumferential edge of the center reflector is fixed to the supporting posts so that the outer circumferential edge of the center reflector can internally touch the supporting posts.

Abstract: An image pick-up apparatus which is capable of increasing an AF area is provided. The image pick-up apparatus includes a photographing lens to focus light received from a subject, a main mirror that passes a portion of light passing through the photographing lens and that reflects the remaining portion of the light, an auto focus module to detect the state of focus the photographing lens and a sub-mirror having a plurality of reflective areas that reflect respectively divided portions of the light passing through the main mirror and that guide the divided light portions to the auto focus module.

Abstract: Apparatus (24), including a photovoltaic cell (22) and a concave primary reflector (26) configured to focus a first portion of incoming radiation toward a focal point (30). The apparatus also includes a secondary reflector (38), which is positioned between the concave primary reflector and the focal point so as to direct the focused radiation toward the photovoltaic cell, and which has a central opening (44) aligned with the photovoltaic cell. The apparatus further includes a transmissive concentrator (54), positioned so as to focus a second portion of the incoming radiation through the central opening onto the photovoltaic cell.

Abstract: A solar energy concentration system that uses a light-guide solar panel (LGSP) to trap light inside a dielectric or other transparent panel and propagates the light to one of the panel edges for harvesting solar energy by a collector such as a photovoltaic cell. This allows for very thin modules whose thickness is comparable to the height of the solar energy collector. This eliminates the depth requirements inherent in traditional concentrated photovoltaic solar energy systems.

Abstract: A quasi-parabolic reflector and method are provided for a solar concentrator which produces a unique radiation pattern which is less susceptible to surface defects, less sensitive to target distance irregularities, and having greater uniformity of intensity for PV applications in comparison to that produced by true parabolic reflectors. Cross-sections of the quasi-parabolic reflector include spaced reflective surfaces which have focal areas spaced one from the other about an axis of symmetry. A method for forming petals of a quasi-parabolic reflector includes stamping them into shape using a stamping apparatus with a higher radius of curvature than the finished petal and iteratively testing and stamping the petal until the petal passes or fails a quality and accuracy threshold.

Abstract: A photonics-based planar solar concentrator designed for collecting and guiding insolate radiation from one side to solar cells for energy conversion on another side is described. The planar solar concentrator consists of two sections. The top section is a matrix of micro-size wide angle solar concentrators. The bottom section is a planar lightwave circuit, which may be multi-layered. Planar lightwave circuits are used within a relatively thin cross-sectional thickness to guide light from micro-concentrators to output apertures on the opposite surface, such that solar cells can be located directly underneath the concentrator. The planar concentrator can deliver multiple times the normal sunlight intensity to standard silicon solar cells, thereby decreasing the number of cells required in a typical solar module. This planar solar concentrator is designed for use as the top optical layer of a standard flat panel solar module.

Abstract: A planar light source device is provided which has high light extraction efficiency and in which a change in color tone at different viewing angles is small. The planar light source device includes, on a light emitting surface, a concavo-convex structure layer made of a resin composition. In this planar light source device, the concavo-convex structure layer has a cone, pyramid, or prism shape, and the resin composition contains a transparent resin and particles. In particular, in the planar light source device, variations in any of x- and y-chromaticity coordinates in any directions in a hemisphere on the light emitting surface are within ±0.1, the diameter of the particle is 10 ?m or less, and the amount of the particles is 1 to 40 wt % based on the total amount of the resin composition. In addition, the difference in refractive index between the particles and the transparent resin is 0.05 to 0.5.

Abstract: Solar panels and assembled arrays thereof include a collection of relatively compact, high-capacity power units. Optical components of each power unit include a front window or surface glazing, a primary mirror, secondary mirror and receiver assembly. Primary and secondary mirrors are defined by respective perimeters, at least a portion of which may be substantially coplanar and in contact with the front window. Some primary mirrors are configured with a perimeter of alternating full and truncated sections, and are curved to a base portion forming a pilot hole therein. Receiver assembly mechanical components include an alignment tube for mating with the primary mirror's pilot hole and for housing a photovoltaic solar cell. A base plate provided adjacent to the alignment tube serves to radiate heat emitted by the solar cell, and in some embodiments an additional heat sink provides further passive cooling.

Abstract: A solar heliostat and system are described with various characteristics particularly suitable for concentrating systems with a relatively large number of small heliostats. Other features contribute to high performance, low cost, high durability, and high temperature operation, such as desired for high efficiency thermal power generation.

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

Abstract: Axial symmetric parabolic reflector comprising an opening and which is positionable in a position in which it surround the at least a led lighting source for reflect and distribute in homogeneous way a light flux toward the opening. The axial symmetric parabolic reflector comprises a mask which is made integral with the same, besides the mask being positionable in proximity of the at least a led lighting source in a way to results substantially orthogonal to a longitudinal direction in order to avoid the direct eyesight of the at least a led lighting source through the opening. The mask further comprises a reflecting surface which includes a reflecting axial symmetric groove having a section substantially shaped as a “3”, and besides at least a filter or a lens in order to avoid the glare by indirect light of the at least a led lighting source.

Abstract: A dish structure (10) has a virtual front surface, the front surface having a periphery, and a plurality of spaced apart non overlapping elongate front beams (16), each of which extends between two points on the periphery. Each front beam (16) has at least one mounting area (20) for receiving a reflective panel (150), the at least one mounting area (20) conforming substantially to the virtual front surface in the longitudinal direction of the front beam (16).

Abstract: A panel of flat mirrors reflect light towards one or more locations. The light reaching the one or more locations is converted into another form of energy.

Abstract: For work in which reflecting mirrors (or facets (31)) to be mounted on a heliostat 3 coincide with a pseudo toroid (53), an adjustment method of, and a mounting posture measuring device for, accurately measuring mounting postures of the respective facets (31) are provided for performing mounting adjustment efficiently and simply. In a method of installing the reflecting mirrors (or the facets (31)) constituting the heliostat 3 for sunlight condensation, each facet (31) is installed in such so that a reflected laser beam (52) reflected by the facet 31 can reach a virtual passage point (52b) in a laser point measuring unit (12).

Abstract: The invention relates to a mirror comprising a glass sheet and a silver layer applied to the glass and provided on its back with a protective coating comprising a layer of dried and crosslinked paint of the alkyd type and a layer of dried and crosslinked paint of the polyurethane type, the alkyd layer being located between the silver layer and the polyurethane layer. The invention also relates to its use for deflecting solar light onto a heat collector. The invention also relates to a process for manufacturing a mirror comprising: a silver layer is deposited on a glass sheet using a silverplating solution; then a layer of alkyd paint having a viscosity of between 25 and 110 seconds measured using a Ford No. 4 cup is applied on the side with the silver layer; then the alkyd paint layer is dried and crosslinked; then a layer of polyurethane paint having a viscosity of between 25 and 110 seconds measured using a Ford No.

Abstract: Longitudinally adjacent plane mirrors (106-114) are pivotally interconnected in a columnar array (56) by non-stretching linkages (120) which constrain movement of the mirrors such that their normal vectors (115) remain parallel. Pivotable couplings (122, 124) in two mirrors permit movement of the mirrors with respect to mutually perpendicular axes (x, y) and prevent movement of the mirrors with respect to a third axis (z). Two actuators (117A, 117B) coupled to one of the pivotable couplings controllably move a selected mirror with respect to the mutually perpendicular axes (x, y). A first frame (116) couples the mirror columns together so that movement of the selected mirror moves all the mirrors in unison. The actuators controllably move the mirrors to orient the normal vectors such that the mirrors specularly reflect incident light in a preselected direction.

Abstract: A reflection device including a sheet made of a flexible material with at least one surface having reflective properties including a first edge and a second edge on opposite sides of a center line of the sheet where the first edge and the second edge of the sheet are shaped such that the flexible material is formed into a mostly parabolic shape in cross section when bent about a line perpendicular to the center line and the sheet is secured at two points along the center line.

Abstract: A direct beam solar lighting system for collecting and distributing sunlight into a room. The system includes a rotatable solar collector head to receive sunlight and to reflect the sunlight downward into a transition tube having a reflective interior surface. The light-concentrating transition tube reflects sunlight into a reflective light tube which directs the reflected sunlight through a plenum space into the room. The system includes a drive mechanism for rotating the rotatable solar collector, and a light fixture at end of the light tube to disburse said reflected sunlight onto a ceiling and a wall in the room. In an embodiment the system includes one or more homogenizing reflectors within the solar collector for collecting the sunlight and directing the sunlight more uniformly over the aperture of the transition tube. In an alternative embodiment, the solar collector includes a rotatable tiltable mirror for providing two-axis tracking.

Abstract: An image display device of the present invention comprises projectors, a reflecting mirror, a screen, an image signal processor which performs a distortion correction, and a base for supporting the projectors, the reflecting mirror, and the screen. The projectors, reflecting mirror, and screen are assembled in one to constitute a single moving unit, and the image display device further comprises a lifting device capable of moving the moving unit in a vertical direction with respect to the base.

Abstract: Various embodiments relate to reflectors comprising a tapered polyhedron including a plurality of substantially planar facets. The reflector may comprise an input end or aperture that is larger than an output end or aperture. The input aperture or end may have a different shape and/or orientation than an output end or aperture. Some embodiments relate to “developable” geometries made of substantially planar facets which, when folded, form a tapered hollow polyhedron that can efficiently receive light (e.g., from a primary reflector or lens) and direct light onto a photovoltaic cell.

Abstract: A solar concentrator device comprising a solar concentrator element comprising a radiation transmissive surface, a radiation absorptive material and a radiation concentrating/collection point and disposed on the incident radiation side thereof a recapture element for recapturing at least a portion of radiation lost from the concentrator element has improved solar radiation collection efficiency by reintroducing recaptured radiation into the concentrator element or by propagating said recaptured radiation through the recapture element to a radiation concentration point associated with the recapture element. It has been found that planar elements having a grooved or corrugated outer surface make for very good recapture elements for planar concentrator elements.

Abstract: A reflective objective is disclosed, in which essentially all the optical power is in a single, off-axis, concave mirror, which is oriented generally perpendicular to the central axis of the objective. An incident beam is directed to and from the concave mirror by a pair of flat mirrors, so that a central on-axis ray in the incident beam is collinear with the corresponding thrice-reflected ray at the object. The object is one focal length away from the concave mirror. The aperture stop is also one focal length away from the concave mirror, leading to a condition of telecentricity at the object. Different focal lengths for the objectives are realized by using mirrors with different curvatures, located at different distances away from the central axis of the objective. The reflective objective can optionally be retrofitted into a turret typically used for microscope objectives, and can optionally have refractive elements, making the objective catadioptric.

Abstract: An optical concentrator having a concentrating element for collecting input light, a redirecting element for receiving the light and also for redirecting the light, and a waveguide including a plurality of incremental portions enabling collection and concentration of the light onto a receiver. Other systems replace the receiver by a light source so the optics can provide illumination.

Abstract: A multi-curvature convex mirror is comprised of a first reflective surface having a first curvature and defined by a portion of the surface area of a greater sphere and a second reflective surface having a second curvature greater than the first curvature and defined by a portion of the surface area of a lesser sphere that intersects the surface area of the greater sphere. The primary and secondary reflective surfaces are comprised of a series of locations, each defined by an x, y, and z coordinate, determined in accordance with the relationship z = x a + y b where 600?a?1,300 and 100?|b?a|?200.

Abstract: An electromagnetic energy concentrating dish (22) that comprises a contoured polymeric support (62) and a reflective surface (60). A contour (26) is determined that will reflect electromagnetic energy from reflective surface (60) to a receiver (36) set at focus region (28). A net or near net polymeric foam (100) is machined to form contoured polymeric support (62) having contour (26?). Reflective surface (60) is laid upon contoured polymeric support (62), and angles of reflection from reflective surface (60) adjust to reflect electromagnetic energy to focus region (28).

Abstract: This invention deals with novel method and apparatus for positioning and motion control of the optical elements (mirrors and lenses) of a Fresnel solar concentrator tracking array which approximately eliminates gravitational torque by use of a central universal pivot or gimbals. Linkage torque is produced by induced and/or permanent dipole coupling to an electronic grid to produce angular deflection, and rotational motion that is enhanced by the presence of highly polarizable material. This system is ideally suited for maximization of solar energy focused by the array onto a receiver. Since there are no mechanical linkages, the instant invention is applicable for fabrication from the mini- to the nano-technology realm. The elimination of gravitational torque by balancing the optical elements on a universal pivot or gimbals greatly reduces the power required for the optical elements to track the sun and focus sunlight onto a receiver.

Abstract: A method of camouflaging a structure against a background having a generally uniform composition of hue, saturation and brightness. In one embodiment, spaced regions on the exterior of a structure are colored with differing colors and regions between the spaced regions are colored with a gradient of the differing colors so as to create a gradual color transition between the spaced regions. In another embodiment, at least one reflector and, optionally at least one color filter, are located on a structure to reflect light in the foreground to a vantage point, and optionally filter such light, so as to effect a blending of at least a portion of the structure into the background when viewed from the vantage point.