Abstract: A temperature measurement device having a thermopile temperature sensor and a proximity sensor, a mobile temperature measurement device, and a method for determining a corrected temperature with a temperature measurement device are described. In an implementation, a temperature measurement device includes a semiconductor device; a thermopile temperature sensor disposed on the semiconductor device, where the thermopile temperature sensor is configured to receive radiation from an object; a proximity sensor disposed on the semiconductor device, the proximity sensor configured to detect a distance between the thermopile temperature sensor and the object; and a controller configured determine a corrected temperature measurement using at least an indication of received radiation and an indication of distance between the thermopile temperature sensor and the object.

Abstract: A device configured to furnish hydration monitoring employs a method using multiple different wavelengths of light transmitted into a human body part, each wavelength being input at a given respective input intensity. Respective output intensities of respective ones of the multiple wavelengths can be measured, upon transmission thereof through the human body part. The corresponding input intensity and the corresponding output intensity for the respective ones of the transmitted wavelengths can be used along with a form of an equation for the Beer-Lambert law to calculate a concentration-related slope, the concentration-related slope being proportional to the relative concentration of water in the human body part at a given time. A hydration-level output indicative of a level of hydration can then be generated based on the concentration-related slope.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: This invention relates to temperature-corrected photoluminescence spectroscopy which may be applied to semiconductors and, in particular, photovoltaic films.

Abstract: This invention relates to temperature-corrected photoluminescence spectroscopy which may be applied to semiconductors and, in particular, photovoltaic films.

Abstract: In one embodiment of the invention, a fuse element for a one time programmable memory may include carbon nanotubes coupled to a first transistor node and to a second transistor node. The carbon nanotubes may have a first resistance which may be changed upon programming the memory cell with low current levels.

Abstract: In one embodiment of the invention, a fuse element for a one time programmable memory may include carbon nanotubes coupled to a first transistor node and to a second transistor node. The carbon nanotubes may have a first resistance which may be changed upon programming the memory cell with low current levels.