Abstract: A concentrator photovoltaic apparatus for controlling internal condensation includes a light receiving module including one or more photovoltaic cells in a waterproof enclosure, at least one primary lens sealed to the waterproof enclosure for concentrating sunlight, a waterproof breather membrane regulating the pressure of the air located inside the enclosure, and a regenerative desiccant in a thermally decoupled dryer tube or thermally coupled to an internal surface of the enclosure. Smaller breather membrane vents and/or positive time delays between the temperature of the desiccant and the temperature of the enclosure may prolong an adsorption phase of the desiccant, which may substantially contribute to efficiency, reliability, and autonomous control of condensation.

Abstract: In a method for fabricating an engineered substrate for semiconductor epitaxy, an array of seed structures is assembled on a surface of the substrate. The seed structures in the array have substantially similar directional orientations of their crystal lattices, and are spatially separated from each other. Semiconductor materials are selectively epitaxially grown on the seed structures, such that a rate of growth of the semiconductor materials on the seed structures is substantially higher than a rate of growth of the semiconductor materials on regions of the surface. The semiconductor materials assume a lattice constant and directional orientation of crystal lattice that are substantially similar or identical to those of the seed structures. Related devices and methods are also discussed.

Abstract: A loopback card includes a connector configured to connect to an IO interface and emulate a storage device interface. The connector includes a port configured to receive a set of signals from the IO interface and transmit them to a redriver. The connector is configured to receive the set of signals from the redriver and transmit them from the redriver to the IO interface. The connector includes control signal inputs configured to receive control signals from the IO interface. The connector further includes one or more logic gates configured to receive the control signals. The one or more logic gates apply a logic operation on the control signals to generate an output and route the output to the IO interface through the connector. The redriver is operably connected to the port and configured to receive the set of signals from the port and transmit them back to the port.

Abstract: A concentrated photovoltaic and display apparatus includes a backplane substrate, a plurality of photovoltaic elements distributed over the backplane substrate, a plurality of display elements distributed over the backplane substrate between the photovoltaic elements, and an optical element positioned over the backplane substrate, the photovoltaic elements, and the display elements. The optical element is configured to concentrate incident light propagating in a direction substantially parallel to an optical axis thereof onto the photovoltaic elements. The optical element is further configured to direct light reflected or emitted from the display elements in a direction that is not substantially parallel to the optical axis of the optical element. Related fabrication methods and arrays including the apparatus are also discussed.

Abstract: A concentrator-type photovoltaic device includes at least one light receiving module having a plurality of photovoltaic devices therein, and a pressure regulating device comprising a volume-adjustable chamber that is pneumatically coupled to the at least one light receiving module. The volume-adjustable chamber may be configured to expand and contract in response to temperature fluctuations within the at least one light receiving module. The volume-adjustable chamber can be made from a flexible metalized film with a low water vapor transmission rate. In this way the module can remain sealed from water penetration and yet maintain uniform internal pressure during thermal excursions. The volume-adjustable chamber may be combined with a desiccant such that, as air moves into the expansion chamber, it passes over the desiccant, which removes moisture that has penetrated into the sealed module.

Abstract: A concentrator photovoltaic apparatus for controlling internal condensation includes a light receiving module including one or more photovoltaic cells in a waterproof enclosure, at least one primary lens sealed to the waterproof enclosure for concentrating sunlight, a waterproof breather membrane regulating the pressure of the air located inside the enclosure, and a regenerative desiccant in a thermally decoupled dryer tube or thermally coupled to an internal surface of the enclosure. Smaller breather membrane vents and/or positive time delays between the temperature of the desiccant and the temperature of the enclosure may prolong an adsorption phase of the desiccant, which may substantially contribute to efficiency, reliability, and autonomous control of condensation.

Abstract: A loopback card includes a connector configured to connect to an IO interface and emulate a storage device interface. The connector includes a port configured to receive a set of signals from the IO interface and transmit them to a redriver. The connector is configured to receive the set of signals from the redriver and transmit them from the redriver to the IO interface. The connector includes control signal inputs configured to receive control signals from the IO interface. The connector further includes one or more logic gates configured to receive the control signals. The one or more logic gates apply a logic operation on the control signals to generate an output and route the output to the IO interface through the connector. The redriver is operably connected to the port and configured to receive the set of signals from the port and transmit them back to the port.

Abstract: CPV modules include a back plate having an array of 1 mm2 or smaller solar cells thereon. A backplane interconnect network is also provided on the back plate. This backplane interconnect network operates to electrically connect the array of solar cells together. A front plate, which is spaced-apart from the back plate, is provided. This front plate includes an array of primary lenses thereon that face the array of solar cells. The front plate can be configured to provide a greater than 1000× lens-to-cell light concentration to the array of solar cells. To achieve this 1000× lens-to-cell light concentration, the primary lenses can be configured as plano-convex lenses having a lens sag of less than about 4 mm. An array of secondary optical elements may also be provided, which extend between the array of primary lenses and the array of solar cells.

Abstract: A feedback controlled laser diode communication device is disclosed that, as is common, has a laser diode that is modulated in response to an input signal to generate an optical signal, encoding the input signal. Spatially variable passband filter material, however, is arranged to receive at least a portion of the optical signal generated by the laser diode, preferably from the rear facet, and at least one detector is used to detect the thus filtered optical signal. Control circuitry then controls a wavelength of the laser diode based upon the response of the detector(s) to thus provide feedback control. As such, the device is particularly applicable to maintaining the tight channel spacings found in wavelength division multiplexed systems.

Abstract: A feedback controlled laser diode communication device is disclosed that, as is common, has a laser diode that is modulated in response to an input signal to generate an optical signal, encoding the input signal. Spatially variable passband filter material, however, is arranged to receive at least a portion of the optical signal generated by the laser diode, preferably from the rear facet, and at least one detector is used to detect the thus filtered optical signal. Control circuitry then controls a wavelength of the laser diode based upon the response of the detector(s) to thus provide feedback control. As such, the device is particularly applicable to maintaining the tight channel spacings found in wavelength division multiplexed systems.