Abstract: Various embodiments are directed to a pressure sensor and method of using the same. A pressure sensor may comprise a substrate having a substrate thickness extending between a first substrate surface and a second substrate surface, wherein the first substrate surface and the second substrate surface define opposing ends of the substrate thickness; a first pressure sensing assembly attached to the first substrate surface and configured to detect a first pressure force associated with a first fluid volume, wherein a portion of the first substrate surface adjacent the first pressure sensing assembly is fluidly isolated from the first volume of fluid; and a second pressure sensing assembly attached to the second substrate surface and configured to detect a second pressure force associated with a second volume of fluid, wherein a portion of the second substrate surface adjacent the second pressure sensing assembly is fluidly isolated from the second fluid volume.

Abstract: A method of charting event occurrence counts includes processing event occurrence data recorded during operation of an industrial process to generate a chart having chart entries representing occurrence counts and chart positioning information. The chart positioning information includes an x-axis with a first time interval between x-positions and a y-axis with a second time interval between y-positions. Respective ones of the chart entries are positioned at intersections between the x-positions and y-positions by placing an element at the intersections having first feature attribute which indicates a relative magnitude of its event count. Time division count sums are computed to indicate a relative magnitude of a count sum across the x-positions and y-positions. The time division count sums are represented with a second feature attribute. The time division count sums are positioned for the x-positions adjacent to the second ending time and for the y-positions adjacent to the first ending time.

Abstract: An apparatus and method for connectivity in networks configured for non-disruptive disconnection of one or more peripheral devices are disclosed. The apparatus includes a first logical layer associated with a first peripheral device, the first peripheral device arranged in a network configured for non-disruptive disconnection of at least one peripheral device, at least a second logical layer associated with at least a second peripheral device, the at least a second peripheral device arranged in the network configured for non-disruptive disconnection of at least one peripheral device, at least one power source associated with the first logical layer and the at least a second logical layer, and a first electrically conductive link coupled to the first logical layer, the at least a second logical layer, and the at least one power source associated with the first logical layer and the at least a second logical layer.

Abstract: Neutron detection cells and corresponding methods of detecting charged particles that make efficient use of silicon area are set forth. Three types of circuit cells/arrays are described: state latching circuits, glitch generating cells, and charge loss circuits. An array of these cells, used in conjunction with a neutron conversion film, increases the area that is sensitive to a strike by a charged particle over that of an array of SRAM cells. The result is a neutron detection cell that uses less power, costs less, and is more suitable for mass production.

Abstract: A method for producing a tantalum sputtering component includes a minimum of three stages each of which include a deformation step followed by an inert atmosphere high-temperature anneal. Temperatures of each of the anneal steps can be different from one another. A tantalum sputtering component includes a mean grain size of less than about 100 microns and a uniform texture throughout the component thickness. The uniform texture can be predominately {111}<uvw>.