Abstract: A package combining a MEMS substrate, a CMOS substrate and another MEMS substrate in one package that is vertically stacked is disclosed. The package comprises a sensor chip further comprising a first MEMS substrate and a CMOS substrate with a first surface and a second surface and where the first MEMS substrate is attached to the first surface of the CMOS substrate. The package further includes a second MEMS substrate with a first surface and a second surface, where the first surface of the second MEMS substrate is attached to the second surface of the CMOS substrate and the second surface of the second MEMS substrate is attached to a packaging substrate. The first MEMS substrate, the CMOS substrate, the second MEMS substrate and the packaging substrate are provided with electrical inter-connects.

Abstract: An example system comprises a microelectromechanical system (MEMS) sensor, a strain gauge, and a strain compensation circuit. The MEMS sensor is operable to generate a sensor output signal that corresponds to a sensed condition (e.g., acceleration, orientation, and/or pressure). The strain gauge is operable to generate a strain measurement signal indicative of a strain on the MEMS sensor. The strain compensation circuit is operable to modify the sensor output signal to compensate for the strain based on the strain measurement signal. The strain compensation circuit stores sensor-strain relationship data indicative of a relationship between the sensor output signal and the strain measurement signal. The strain compensation circuit is operable to use the sensor-strain relationship data for the modifying of the sensor output signal. The modification of the sensor output signal comprises one or both of: removal of an offset from the sensor signal, and application of a gain to the sensor signal.

Abstract: A MEMS sensor is disclosed. The MEMS sensor includes a MEMS structure and a substrate coupled to the MEMS structure. The substrate includes a layer of metal and a layer of dielectric material. The MEMS structure moves in response to an excitation. A first over-travel stop is formed on the substrate at a first distance from the MEMS structure. A second over-travel stop on the substrate at a second distance from the MEMS structure. At least one electrode on the substrate at a third distance from the MEMS structure. The first, second and third distances are all different.

Abstract: A package combining a MEMS substrate, a CMOS substrate and another MEMS substrate in one package that is vertically stacked is disclosed. The package comprises a sensor chip further comprising a first MEMS substrate and a CMOS substrate with a first surface and a second surface and where the first MEMS substrate is attached to the first surface of the CMOS substrate. The package further includes a second MEMS substrate with a first surface and a second surface, where the first surface of the second MEMS substrate is attached to the second surface of the CMOS substrate and the second surface of the second MEMS substrate is attached to a packaging substrate. The first MEMS substrate, the CMOS substrate, the second MEMS substrate and the packaging substrate are provided with electrical inter-connects.

Abstract: A system and/or method for utilizing mechanical motion limiters to control proof mass amplitude in MEMS devices (e.g., MEMS devices having resonant MEMS structures, for example various implementations of gyroscopes, magnetometers, accelerometers, etc.). As a non-limiting example, amplitude control for a MEMS gyroscope proof mass may be accomplished during normal (e.g., steady state) gyroscope operation utilizing impact stops (e.g., bump stops) of various designs. As another non-limiting example, amplitude control for a MEMS gyroscope proof mass may be accomplished utilizing non-impact limiters (e.g., springs) of various designs, for example springs exhibiting non-linear stiffness characteristics through at least a portion of their normal range of operation.

Abstract: An example system comprises a microelectromechanical system (MEMS) sensor, a strain gauge, and a strain compensation circuit. The MEMS sensor is operable to generate a sensor output signal that corresponds to a sensed condition (e.g., acceleration, orientation, and/or pressure). The strain gauge is operable to generate a strain measurement signal indicative of a strain on the MEMS sensor. The strain compensation circuit is operable to modify the sensor output signal to compensate for the strain based on the strain measurement signal. The strain compensation circuit stores sensor-strain relationship data indicative of a relationship between the sensor output signal and the strain measurement signal. The strain compensation circuit is operable to use the sensor-strain relationship data for the modifying of the sensor output signal. The modification of the sensor output signal comprises one or both of: removal of an offset from the sensor signal, and application of a gain to the sensor signal.

Abstract: In accordance with an example embodiment of this disclosure, a micro-electro-mechanical system (MEMS) device comprises a substrate, a CMOS die, and a MEMS die, each of which comprises a top side and a bottom side. The bottom side of the CMOS die is coupled to the top side of the substrate, and the MEMS die is coupled to the top side of the CMOS die, and there is a cavity positioned between the CMOS die and the substrate. The cavity may be sealed by a sealing substance, and may be filled with a filler substance (e.g., an adhesive) that is different than the sealing substance (e.g., a gaseous or non-gaseous substance). The cavity may be fully or partially surrounded by one or more downward-protruding portions of the CMOS die and/or one or more upward-protruding portions of the substrate.

Abstract: An intravenous catheter securement device comprises of an intravenous catheter board stabilizer that conforms to patients' bodies and an adjustable elastic sleeve with a hole for catheter insertion, with two overlying flaps for catheter securement. The intravenous catheter board base has holes on either side, one side for connection of the elastic sleeve, and the other side provides a fastening location for elastic bands attached to the sleeve for tightness adjustment. An embodiment of the invention involving the intravenous board is displayed separately as an alternative innovation. This device is comprised of a simple form fitting elastic sleeve having a catheter opening with the intent of applying a removable adhesive to the sleeve itself over the catheter for securement purposes. These embodiments establish a simple, standardized, and safe method of securing intravenous catheters sans adhesive material in contact with the epidermis.

Abstract: In accordance with an example embodiment of this disclosure, a micro-electromechanical system (MEMS) device comprises a substrate, a CMOS die, and a MEMS die, each of which comprises a top side and a bottom side. The bottom side of the CMOS die is coupled to the top side of the substrate, and the MEMS die is coupled to the top side of the CMOS die, and there is a cavity positioned between the CMOS die and the substrate. The cavity may be sealed by a sealing substance, and may be filled with a filler substance (e.g., an adhesive) that is different than the sealing substance (e.g., a gaseous or non-gaseous substance). The cavity may be fully or partially surrounded by one or more downward-protruding portions of the CMOS die and/or one or more upward-protruding portions of the substrate.

Abstract: In accordance with an example embodiment of this disclosure, a micro-electro-mechanical system (MEMS) device comprises a substrate, a CMOS die, and a MEMS die, each of which comprises a top side and a bottom side. The bottom side of the CMOS die is coupled to the top side of the substrate, and the MEMS die is coupled to the top side of the CMOS die, and there is a cavity positioned between the CMOS die and the substrate. The cavity may be sealed by a sealing substance, and may be filled with a filler substance (e.g., an adhesive) that is different than the sealing substance (e.g., a gaseous or non-gaseous substance). The cavity may be fully or partially surrounded by one or more downward-protruding portions of the CMOS die and/or one or more upward-protruding portions of the substrate.

Abstract: A MEMS sensor is disclosed. The MEMS sensor includes a MEMS structure and a substrate coupled to the MEMS structure. The substrate includes a layer of metal and a layer of dielectric material. The MEMS structure moves in response to an excitation. A first over-travel stop is formed on the substrate at a first distance from the MEMS structure. A second over-travel stop on the substrate at a second distance from the MEMS structure. At least one electrode on the substrate at a third distance from the MEMS structure. The first, second and third distances are all different.

Abstract: A system and method for providing a MEMS device with integrated electronics are disclosed. The MEMS device comprises an integrated circuit substrate and a MEMS subassembly coupled to the integrated circuit substrate. The integrated circuit substrate includes at least one circuit coupled to at least one fixed electrode. The MEMS subassembly includes at least one standoff formed by a lithographic process, a flexible plate with a top surface and a bottom surface, and a MEMS electrode coupled to the flexible plate and electrically coupled to the at least one standoff. A force acting on the flexible plate causes a change in a gap between the MEMS electrode and the at least one fixed electrode.