Abstract: Systems and methods for isolated sensor device protection are provided. In one embodiment, an isolated sensor device comprises: a housing having an isolation chamber; an isolator sealed within the isolation chamber; an inertial sensor assembly sealed within the isolation chamber, the inertial sensor assembly coupled to an inner surface of the isolation chamber by the isolator; and at least one progressive impact interface applied to a periphery of the inertial sensor assembly, wherein the at least one progressive impact interface extends outward from the inertial sensor assembly towards the inner surface.

Abstract: Systems and methods for isolated sensor device protection are provided. In one embodiment, an isolated sensor device comprises: a housing having an isolation chamber; an isolator sealed within the isolation chamber; an inertial sensor assembly sealed within the isolation chamber, the inertial sensor assembly coupled to an inner surface of the isolation chamber by the isolator; and at least one progressive impact interface applied to a periphery of the inertial sensor assembly, wherein the at least one progressive impact interface extends outward from the inertial sensor assembly towards the inner surface.

Abstract: Systems and method for reducing the size of inertial measurement units are disclosed. In one embodiment, an inertial measurement unit assembly comprises: at least one inertial sensor configured to output uncompensated sensor data; an inertial isolator configured to isolate the at least one inertial sensor; an interface adapter, wherein the interface adapter includes at least one calibration alignment pin that is used as a reference point between the at least one inertial sensor, the inertial interface adapter and a vehicle to which the inertial interface adapter is attached. Furthermore, the inertial measurement unit is configured to output the uncompensated sensor data to a processing device located external to the inertial measurement unit.

Abstract: An inertial measurement unit includes a housing with openings to permit fluid communication between at least one pressure source and two distinct cavities within the housing. The cavities are separated by an inertial sensor assembly coupled to a vibration isolator assembly. The pressure in the cavities may be adjusted or tuned to change a natural frequency of the inertial measurement unit, thus allowing the unit to be configured and even optimized for a variety of different applications. By adjusting the pressure in the respective cavities, gas squeeze film damping effects may be optimized when the inertial measurement unit undergoes a shock event and/or when the inertial measurement unit experiences vibration loads during operation. In one embodiment, the vibration isolator assembly includes perforations to permit fluid communication between the first and second cavities during specific operational events.