| Patent application number | Description | Published |
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| 20090168385 | FLEX CIRCUIT SNAP TRACK FOR A BIOMETRIC SENSOR - The present disclosure relates to a sensor assembly, comprising a frame comprising structural supports, and housings configured to house an optical component; and a strut disposed between one of the structural supports and housings; wherein the struts are adapted to house conductors connecting the optical component to a circuit. | 07-02-2009 |
| 20090171224 | SENSOR WITH INTEGRATED LIVING HINGE AND SPRING - Embodiments of the present disclosure relate generally to a sensor assembly. In various embodiments the sensor assembly includes a body having a first segment, a second segment, and a living hinge. The living hinge has a pivot axis and mechanically couples the first segment and the second segment. Further, the living hinge facilitates the first segment and the second segment to pivoting relative to one another about the pivot axis. Embodiments may also relate to a method of manufacturing a sensor frame. The method may include forming an integral sensor body having a first frame segment, a second frame segment, and a living hinge. The first frame segment and the second frame segment are configured to pivot relative to one another about a pivot axis of the living hinge. The method may also include coupling one or more biasing mechanisms to the first frame segment and the second frame segment. The biasing mechanism is configured to generate a moment about the pivot axis of the living hinge. The moment biases the first segment and second segment into a closed position. | 07-02-2009 |
| 20090264723 | COMPLIANT DIAPHRAGM MEDICAL SENSOR AND TECHNIQUE FOR USING THE SAME - A sensor assembly is provided that includes a frame having a loop structure. An emitter and detector are disposed on opposite sides of the loop structure. A coating is provided over the frame. The coating includes at least one diaphragm structure disposed such that at least one of the emitter and detector can move along an axis running between the emitter and detector. The sensor may thereby be placed on a patient's finger, toe, and so forth to obtain pulse oximetry or other physiological measurements. A sensor frame and method of manufacturing the frame are also provided. | 10-22-2009 |
| 20090308531 | BI-STABLE MEDICAL SENSOR AND TECHNIQUE FOR USING THE SAME - A bi-stable sensor is provided that includes a frame upon which electrical and optical components may be disposed and a coating, such as an overmold coating, provided about the frame. A resistance-providing component is provided integral with or external to the coated bi-stable sensor such that the bi-stable sensor has two mechanically stable configurations that may be transitioned between by overcoming the resistance provided by the resistance-providing component and/or the by the coating. In one embodiment, the resistance-providing component comprises an elastic band provided about a hinge of the frame, either within or external to the coating. In one embodiment, the sensor may be placed on a patient's finger, toe, ear, and so forth to obtain pulse oximetry or other physiological measurements. | 12-17-2009 |
| 20100280582 | DEVICE, SYSTEM AND METHOD OF REMOVING HEAT FROM SUBCUTANEOUS LIPID-RICH CELLS - Devices, systems and methods for removing heat from subcutaneously disposed lipid-rich cells are disclosed. In selected embodiments, suction and/or heat removal sources are coupled to an applicator. The applicator includes a flexible portion and a rigid portion. The rigid portion includes a thermally conductive plate and a frame coupling the thermally conductive plate and the flexible portion. An interior cavity of the applicator is in fluid communication with the suction source, and the frame maintains contiguous engagement between the heat removal source and the thermally conductive plate. | 11-04-2010 |
| Patent application number | Description | Published |
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| 20080295882 | PHOTOVOLTAIC DEVICE AND METHOD OF MANUFACTURING PHOTOVOLTAIC DEVICES - A photovoltaic device includes a supporting layer, a semiconductor layer stack, and a conductive and light transmissive layer. The supporting layer is proximate to a bottom surface of the device. The semiconductor layer stack includes first and second semiconductor sub-layers, with the second sub-layer having a crystalline traction of at least approximately 85%. A conductive and light transmissive layer between the supporting layer and the semiconductor layer stack, where an Ohmic contact exists between the first semiconductor sub-layer and the conductive and light transmissive layer. | 12-04-2008 |
| 20100078064 | MONOLITHICALLY-INTEGRATED SOLAR MODULE - A solar module includes a substrate, a plurality of electrically interconnected solar cells, and an upper separation gap. The solar cells are provided above the substrate. At least one of the solar cells includes a reflective electrode, a silicon layer stack and a light transmissive electrode. The reflective electrode is provided above the substrate. The silicon layer stack includes an n-doped layer provided above the reflective electrode, an intrinsic layer provided above the n-doped layer and a p-doped layer provided above the intrinsic layer. The light transmissive electrode is provided above the silicon layer stack. The upper separation gap is provided between the cells. The upper separation gap electrically separates the light transmissive electrodes in the solar cells from one another such that the light transmissive electrode of one of the solar cells is electrically connected to the reflective electrode of another one of the solar cells. | 04-01-2010 |
| 20100282314 | PHOTOVOLTAIC CELLS AND METHODS TO ENHANCE LIGHT TRAPPING IN SEMICONDUCTOR LAYER STACKS - A photovoltaic cell includes a substrate, a semiconductor layer stack, a reflective and conductive electrode layer, and a textured template layer. The semiconductor layer stack is disposed above the substrate. The electrode layer is located between the substrate and the semiconductor layer stack. The template layer is between the substrate and the electrode layer. The template layer includes an undulating upper surface that imparts a predetermined shape to the electrode layer. The electrode layer reflects light back into the semiconductor layer stack based on the predetermined shape of the electrode layer. | 11-11-2010 |
| 20100313935 | PHOTOVOLTAIC MODULES AND METHODS FOR MANUFACTURING PHOTOVOLTAIC MODULES HAVING TANDEM SEMICONDUCTOR LAYER STACKS - A monolithically-integrated photovoltaic module is provided. The module includes an insulating substrate and a lower electrode above the substrate. The method also includes a lower stack of microcrystalline silicon layers above the lower electrode, an upper stack of amorphous silicon layers above the lower stack, and an upper electrode above the upper stack. The upper and lower stacks of silicon layers have different energy band gaps. The module also includes a built-in bypass diode vertically extending in the upper and lower stacks of silicon layers from the lower electrode to the upper electrode. The built-in bypass diode includes portions of the lower and upper stacks that have a greater crystalline portion than a remainder of the lower and upper stacks. | 12-16-2010 |
