Abstract: A pressure sensor assembly, which includes a support substrate, circuitry mounted to the support substrate, at least one conductor mounted to the support substrate and in electrical communication with the circuitry, and at least one vertically conductive path connected to and in electrical communication with the at least one conductor. The pressure sensor assembly also includes a diaphragm, at least one sealing glass section connected to the diaphragm and the support substrate, and at least one lateral conductive feed-through mounted to the diaphragm. At least one conductive joint is connected to the vertically conductive path and the lateral conductive feed-through, and the conductive joint provides electrical communication between the vertically conductive path and the lateral conductive feed-through.

Abstract: A pressure sensor assembly, which includes a support substrate, circuitry mounted to the support substrate, at least one conductor mounted to the support substrate and in electrical communication with the circuitry, and at least one vertically conductive path connected to and in electrical communication with the at least one conductor. The pressure sensor assembly also includes a diaphragm, at least one sealing glass section connected to the diaphragm and the support substrate, and at least one lateral conductive feed-through mounted to the diaphragm. At least one conductive joint is connected to the vertically conductive path and the lateral conductive feed-through, and the conductive joint provides electrical communication between the vertically conductive path and the lateral conductive feed-through.

Abstract: A micro-electromechanical pressure transducer formed from a silicon die centers itself on a pedestal, formed from either a metal or a dielectric, by applying a predetermined amount of liquid epoxy adhesive to the square, top surface of the pedestal and allowing the liquid adhesive to distribute itself over the top surface. A MEMS die placed atop the liquid adhesive is centered on the top surface by surface tension between sides of the die and the top surface.

Abstract: A micro-electromechanical pressure transducer formed from a silicon die centers itself on a pedestal, formed from either a metal or a dielectric, by applying a predetermined amount of liquid epoxy adhesive to the square, top surface of the pedestal and allowing the liquid adhesive to distribute itself over the top surface. A MEMS die placed atop the liquid adhesive is centered on the top surface by surface tension between sides of the die and the top surface.

Abstract: Thermally-induced stress on a silicon micro-electromechanical pressure transducer (MEMS sensor) is reduced by attaching the MEMS sensor to a plastic filled with low CTE fillers that lowers the plastic's coefficient of thermal expansion (CTE) to be closer to that of silicon. The MEMS sensor is attached to the housing using an epoxy adhesive/silica filler mixture, which when cured has a CTE between about ten PPM/° C. and about thirty PPM/° C. in order to match the housing CTE. The adhesive also has a glass transition temperature (Tg) above the operating temperature range. This design provides good sealing of the sensor and stable sensor outputs.

Abstract: Thermally-induced stress on a silicon micro-electromechanical pressure transducer (MEMS sensor) is reduced by attaching the MEMS sensor to a plastic filled with low CTE fillers that lowers the plastic's coefficient of thermal expansion (CTE) to be closer to that of silicon. The MEMS sensor is attached to the housing using an epoxy adhesive/silica filler mixture, which when cured has a CTE between about ten PPM/° C. and about thirty PPM/° C. in order to match the housing CTE. The adhesive also has a glass transition temperature (Tg) above the operating temperature range. This design provides good sealing of the sensor and stable sensor outputs.

Abstract: A method of separating a thin die (20, 60) from a support body (72) of a semiconductor wafer (70). The thin die (20, 60) being initially attached to the support body (72) by an attachment mechanism (78, 178). The attachment mechanism may be a plurality of tethers (78, 178) that extend between the thin die (20, 60) and the support body (72).

Abstract: A method of separating a thin die (20, 60) from a support body (72) of a semiconductor wafer (70). The thin die (20, 60) being initially attached to the support body (72) by an attachment mechanism (78, 178). The attachment mechanism may be a plurality of tethers (78, 178) that extend between the thin die (20, 60) and the support body (72).