Disclosed herein are aspects of a multiple-mass, multi-axis microelectromechanical systems (MEMS) accelerometer sensor device with a fully differential sensing design that applies differential drive signals to movable proof masses and senses differential motion signals at sense fingers coupled to a substrate. In some embodiments, capacitance signals from different sense fingers are combined together at a sensing signal node disposed on the substrate supporting the proof masses. In some embodiments, a split shield may be provided, with a first shield underneath a proof mass coupled to the same drive signal applied to the proof mass and a second shield electrically isolated from the first shield provided underneath the sense fingers and biased with a constant voltage to provide shielding for the sense fingers.

The present disclosure relates to a contextual service device and method of use to identify an operator's needs, such as in the event a vehicle crash, vehicle breakdown, theft, and/or vehicle related quarry in real time. In various aspects, the device is self-sufficient and may be installed and activated in a single step. Furthermore, the device is not reliant upon external systems of components of the vehicle to operate and may be updated over the air to improve cash detection accuracy.

The present disclosure relates to a contextual service device and method of use to identify an operator's needs, such as in the event a vehicle crash, vehicle breakdown, theft, and/or vehicle related quarry in real time. In various aspects, the device is self-sufficient and may be installed and activated in a single step. Furthermore, the device is not reliant upon external systems of components of the vehicle to operate and may be updated over the air to improve cash detection accuracy.

An inertial measurement unit with distributed sensors to provide superior accuracy for acceleration, angular velocity and in some cases orientation. By using a distributed sensor configuration, improved accuracy is possible by leveraging the geometric configuration of the sensor array. The devices and methods described below provide for a distributed sensor IMU with distributed accelerometers, in addition to optionally distributed magnetometers and a further optional gyroscope.

An inertial measurement unit with distributed sensors to provide superior accuracy for acceleration, angular velocity and in some cases orientation. By using a distributed sensor configuration, improved accuracy is possible by leveraging the geometric configuration of the sensor array. The devices and methods described below provide for a distributed sensor IMU with distributed accelerometers, in addition to optionally distributed magnetometers and a further optional gyroscope.

A shot detection system for a projectile weapon comprising: an accelerometer, a power source, a memory; and a processor configured to: receive accelerometer data from the accelerometer; for a first region of interest, test a first property of the accelerometer data; and store a shot determination result in the memory.

A shot detection system for a projectile weapon comprising: an accelerometer, a power source, a memory; and a processor configured to: receive accelerometer data from the accelerometer; for a first region of interest, test a first property of the accelerometer data; and store a shot determination result in the memory.

An earphone including a proximity sensor, an acceleration sensor, and a signal analysis device. The signal analysis device identifies an approaching movement of the earphone to an object using the proximity sensor signal. The signal analysis device ascertains whether the approaching movement is a movement of the earphone to an ear of the user. By filtering the acceleration sensor signal, the signal analysis device generates a high-pass filtered acceleration signal and a low-pass filtered acceleration signal. The signal analysis device determines an end time of the approaching movement based on a stabilization of the acceleration, using the low-pass filtered acceleration signal. The signal analysis device confirms that the approaching movement is a movement of the earphone to an ear of the user based on changes in the high-pass filtered acceleration signal after the ascertained end time of the approaching movement.

An earphone including a proximity sensor, an acceleration sensor, and a signal analysis device. The signal analysis device identifies an approaching movement of the earphone to an object using the proximity sensor signal. The signal analysis device ascertains whether the approaching movement is a movement of the earphone to an ear of the user. By filtering the acceleration sensor signal, the signal analysis device generates a high-pass filtered acceleration signal and a low-pass filtered acceleration signal. The signal analysis device determines an end time of the approaching movement based on a stabilization of the acceleration, using the low-pass filtered acceleration signal. The signal analysis device confirms that the approaching movement is a movement of the earphone to an ear of the user based on changes in the high-pass filtered acceleration signal after the ascertained end time of the approaching movement.

A structure state display system has a measurement means, disposed in a structure, for measuring a physical state relating to the structure, an acquisition means for acquiring measurement information measured with the measurement means, and a creation means for applying a virtual physical quantity according to the measurement information to a design model including the structure and creating a virtual model in which a display showing the physical state of the structure in the design model is changed, and the virtual model is displayed on display means.