Abstract: A solar cell array including a matrix of solar cells arranged on a substrate in rows and columns; and a plurality of conductor elements connecting the solar cells within each column in parallel and the solar cells of each row in series. The conductor elements are arranged on the substrate in an optical path of light to the solar cells. The conductor elements are physically dimensioned to reduce interference with the optical path and have current-carrying capacity configured to conduct current within a predetermined range of anticipated operating currents.

Abstract: The physical 3D renderer described herein renders one or more captured depth images as a physical 3D rendering. The physical 3D renderer can render physical 3D surfaces and structures in real time. In one embodiment the 3D renderer creates a physical three dimensional (3D) topological surface from captured images. To this end, a depth image of a surface or structure to be replicated is received (for example from a depth camera or depth sensor). Depth information is determined at a dense distribution of points corresponding to points in the depth image. In one embodiment the depth information corresponding to the depth image is fed to actuators on sliding shafts in an array. Each sliding shaft is adjusted to the depth in the depth image to create a physical 3D topological surface like the surface or structure to be replicated.

Abstract: A frame for mounting a plurality of solar tracking units is provided. The frame comprises a plurality of leg assemblies interconnected by trusses to provide a stable structure that is ballasted by the frame's own weight, rather than relying on external ballast such as concrete blocks. Each leg assembly is provided with a shaft with a mounting end for mounting a solar tracking unit. Each solar tracking unit includes an armature assembly and at least one motor for controlling the orientation and position of a solar panel mounted thereon. Solar tracking assemblies, each comprising the frame and plurality of solar tracking units, can be assembled in an array using connectors spacing the assemblies, thus providing enhanced stability. Each of the assemblies can be provided with a local control unit for controlling each individual solar tracking unit, and a global control unit may be used to control the local control units.

Abstract: Light panels, and methods of providing the light panels, are described. The described light panels are substantially transparent and can operate as an illumination device or as a solar panel. An example light panel includes a first optic layer for transmitting light; a second optic layer with a reflective surface configured for one of directing light from the first optic layer and directing light to the first optic layer; and a receiving assembly disposed between the first optic layer and the second optic layer. The receiving assembly includes a first receiving layer adjacent to the first optic layer; a second receiving layer adjacent to the second optic layer and separated from the first receiving layer; and a light device coupled to the first receiving layer. The light device can be configured to receive light from the reflective surface or to provide light to the reflective surface.

Abstract: A frame for mounting a plurality of solar tracking units is provided. The frame comprises a plurality of leg assemblies interconnected by trusses to provide a stable structure that is ballasted by the frame's own weight, rather than relying on external ballast such as concrete blocks. Each leg assembly is provided with a shaft with a mounting end for mounting a solar tracking unit. Each solar tracking unit includes an armature assembly and at least one motor for controlling the orientation and position of a solar panel mounted thereon. Solar tracking assemblies, each comprising the frame and plurality of solar tracking units, can be assembled in an array using connectors spacing the assemblies, thus providing enhanced stability. Each of the assemblies can be provided with a local control unit for controlling each individual solar tracking unit, and a global control unit may be used to control the local control units.

Abstract: Concentrated photovoltaic panel comprises: (1) a receiver substrate assembly including: (a) a rigid sheet of light transmissive material having a first surface, a second surface opposite the first surface, and a conductor pattern attached to the first surface; and (b) at least one receiver assembly affixed to the rigid sheet, each receiver assembly including a photovoltaic cell in electrical communication with the conductor pattern; and (2) at least one light-guide optic attached to and supported by the receiver substrate assembly, each light-guide optic in optical communication with the photovoltaic cell of an associated one of the at least one receiver assembly for guiding light received via the receiver substrate assembly toward said photovoltaic cell.

Abstract: Illumination panel comprises: (1) a receiver substrate assembly including: (a) a rigid sheet of light transmissive material having a first surface, a second surface opposite the first surface, and a conductor pattern attached to the first surface; and (b) at least one receiver assembly affixed to the rigid sheet, each receiver assembly including a light source in electrical communication with the conductor pattern; and (2) at least one light-guide optic attached to and supported by the receiver substrate assembly, each light-guide optic in optical communication with the photovoltaic cell of an associated one of the at least one receiver assembly for guiding light for output via the rigid sheet.

Abstract: Optics are provided for use in illumination devices the optics having a light guide, a redirecting layer including a plurality of lenses, and a plurality of reflector elements. Light from a light source enters the light guide and is guided therein until it escapes into a reflector element, which reflects at least some of the light received by the reflector element toward a corresponding lens for emission from the illumination device.

Abstract: Optics are provided for use in solar concentrators, the optics having a light guide, a redirecting layer including a plurality of lenses, and a plurality of reflector elements. Sunlight is received by the redirecting lenses, which focus the sunlight onto reflective surfaces of the reflector elements. The reflective surface of each reflector element redirects the light into the light guide, which guides the light toward a solar energy collector, such as a photovoltaic cell. The light from the light guide may be directed onto the solar energy collector by a light conditioning element.

Abstract: A concentrated photovoltaic panel comprises at least one rigid sheet, one or more first optical elements disposed adjacent a first side of the at least one rigid sheet, one or more second optical elements disposed adjacent a second side of the at least one rigid sheet, and one or more photovoltaic elements. Each photovoltaic element is disposed between a respective first optical element and a respective second optical element. Each first optical element comprises at least one lens configured to focus light impinging thereon onto a corresponding reflecting surface of the respective second optical element. Each second optical element is configured to reflect light focused by the first optical element to the photovoltaic element disposed therebetween.

Abstract: Device for providing comprising: A panel having rigid layer having a patterned electrical circuit thereon. An array of illuminating units, each unit being formed by at least one rigid element and a portion of the rigid layer; and including: a rigid optical dispersing element, a light source sandwiched within the panel for generating light from electrical energy, and an electrical conductor. The electrical conductor being the primary heat sink for the light source, the light source being primarily cooled via conduction. The electrical conductor and the optical dispersing element being dimensioned and arranged within the unit such that the electrical conductor does not materially impede transmission of light generated by the light source to the outside of the device. The electrical conductor transmitting electrical and thermal energy received from the light source away from the unit.

Abstract: Device for concentrating and harvesting sunlight comprising: A panel having rigid layer having a patterned electrical circuit thereon. An array of sunlight concentrating and harvesting units, each unit being formed by at least one rigid element and a portion of the rigid layer; and including: a rigid optical concentrating element, a photovoltaic cell sandwiched within the panel for converting sunlight into electrical energy, and an electrical conductor. The electrical conductor being the primary heat sink for the photovoltaic cell, the photovoltaic cell being primarily cooled via conduction. The electrical conductor and the optical concentrating element being dimensioned and arranged within the unit such that the electrical conductor does not materially impede transmission of sunlight to the photovoltaic cell. The electrical conductor transmitting electrical and thermal energy received from the photovoltaic cell away from the unit.

Abstract: A frame for mounting a plurality of solar tracking units is provided. The frame comprises a plurality of leg assemblies interconnected by trusses to provide a stable structure that is ballasted by the frame's own weight, rather than relying on external ballast such as concrete blocks. Each leg assembly is provided with a shaft with a mounting end for mounting a solar tracking unit. Each solar tracking unit includes an armature assembly and at least one motor for controlling the orientation and position of a solar panel mounted thereon. Solar tracking assemblies, each comprising the frame and plurality of solar tracking units, can be assembled in an array using connectors spacing the assemblies, thus providing enhanced stability. Each of the assemblies can be provided with a local control unit for controlling each individual solar tracking unit, and a global control unit may be used to control the local control units.

Abstract: An uplock assembly for retaining and releasing landing gear systems, said uplock assembly comprising: a thermal actuator comprising: a chamber configured to contain expansible material therein; a heating mechanism coupled to said chamber for heating said expansible material and causing volumetric expansion thereof; a piston slidably coupled to said chamber and adapted to extend in response to said volumetric expansion; and an uplock release mechanism releasably engaged by said piston when extended such that said engaged uplock release mechanism causes the release of said landing gear.

Abstract: In an embodiment, a system includes a plurality of ports and a proximity detection circuit to detect the presence of a connector relative to at least one port of the plurality of ports, prior to engagement of the connector with the port. Alternatives include a position sensor to determine the general distance of the connector from the port, and an orientation sensor to determine the orientation of the connector relative to the port. The system further includes a signal generator to provide at least one user-detectable signal representative of one or more of the proximity, position and orientation of the connector relative to the port to assist a user in engaging the connector with the port.

Abstract: A photovoltaic (PV) generating system that includes a plurality of PV tracker units, each having: a PV panel with a plurality of PV generators connected to output electrical power and an actuator for positioning the PV panel. A multiple tracker control unit is in communication with the plurality of PV tracker units, the tracker control unit monitoring the output electrical power of the PV panels and controlling, in dependance on the monitored output electrical power, both: (i) power conversion of the output electrical power and (ii) the actuators of the PV tracker units, to optimize power output for the plurality of PV tracker units.

Abstract: Systems and methods implement a rules-based decision engine that identifies vehicles with a high total loss potential based on vehicle details and damage information. This can be done by applying weights to the various criteria and comparing a sum of the applied weights to a threshold. An update mode allows for the subsequent update of the determination of whether the vehicle is a likely total loss based on additionally acquired information.

Abstract: The present invention includes methods and technologies for defining and administering device manners policy (“DMP”), propagating DMP, reception and recognition of, and compliance with DMP. Such policy may be used to communicate to various mobile and other devices the “manners” with which compliance is expected or required. Similar to some of the social manners honored among people, such as with “no smoking” or “employees only” zones, “no swimming” or “no flash photography” areas, and scenarios for “please wash your hands” or “no talking out loud”, devices may recognize and comply with analogous “device manners” policy.

Abstract: The present invention includes methods and technologies for defining and administering device manners policy (“DMP”), propagating DMP, reception and recognition of, and compliance with DMP. Such policy may be used to communicate to various mobile and other devices the “manners” with which compliance is expected or required. Similar to some of the social manners honored among people, such as with “no smoking” or “employees only” zones, “no swimming” or “no flash photography” areas, and scenarios for “please wash your hands” or “no talking out loud”, devices may recognize and comply with analogous “device manners” policy.