A signal processing method includes a processing target signal generation step of generating a processing target signal which is a time-series signal based on a source signal which is a time-series signal output from an object, and a vibration rectification error calculation step of calculating a plurality of vibration rectification errors by performing product-sum operation processing of a first signal based on the processing target signal and a second signal based on a phase-shifted signal of the processing target signal a plurality of times by changing a shift amount.

The inertial sensor includes a substrate, stationary electrodes provided to the substrate, an element section including a movable body which is displaceable with respect to the stationary electrodes, and which has electrodes in a first portion and a second portion opposed to the stationary electrodes, a protrusion which limits a displacement of the movable body, and which has a detection electrode in a portion opposed to the first portion of the movable body, a drive circuit for outputting a drive signal to the element section, a contact detection circuit for outputting a detection signal due to a contact between the electrode in the first portion of the movable body and the detection electrode of the protrusion, a self-diagnostic circuit for outputting a test signal to the element section when receiving the detection signal from the contact detection circuit, and a determination circuit for determining whether or not a level of a signal output by the element section in response to the test signal is out of a threshold value.

The inertial sensor includes a substrate, stationary electrodes provided to the substrate, an element section including a movable body which is displaceable with respect to the stationary electrodes, and which has electrodes in a first portion and a second portion opposed to the stationary electrodes, a protrusion which limits a displacement of the movable body, and which has a detection electrode in a portion opposed to the first portion of the movable body, a drive circuit for outputting a drive signal to the element section, a contact detection circuit for outputting a detection signal due to a contact between the electrode in the first portion of the movable body and the detection electrode of the protrusion, a self-diagnostic circuit for outputting a test signal to the element section when receiving the detection signal from the contact detection circuit, and a determination circuit for determining whether or not a level of a signal output by the element section in response to the test signal is out of a threshold value.

The present description concerns a microelectromechanical sensor control method, including the steps of: exciting, with same first signal (FSL), a first resonant (206L) and at least one second resonant element (206R); and estimating a phase shift (Δφ) between the first signal and a second signal (FSR) which is an image of vibrations of the second resonant element.

Sensor apparatus and methods for operating the same for measuring acceleration are disclosed. In some embodiments, circuitry inside a sensor digitizes a measured acceleration signal from an accelerometer into a digitized acceleration signal, which is processed by a digital equalization filter within the sensor to provide an equalized acceleration signal. The equalized acceleration signal may have a frequency response that is substantially flat over a frequency range that extends beyond the resonant frequency of a MEMs sensor within the accelerometer of the sensor.

A sensor signal generation device includes a charge amplifier and a voltage amplifier circuit that convert a physical quantity of an observation target outputted from a sensor element into a voltage signal and output the voltage signal, and a correction unit that outputs a sensor signal obtained by correcting the voltage signal using frequency characteristics of the charge amplifier and the voltage amplifier circuit.

Provided is a sensor that is highly accurate while ensuring reduced power consumption. A sensor is an electronic circuit that includes a sensor element, an analog filter, an A/D converter, and first and second electronic circuit. The analog filter filters a waveform that includes a sensor signal from the sensor element and noise based on a servo signal. The A/D converter converts the waveform filtered by the analog filter into a first digital signal. The first electronic circuit includes a digital filter and acquires a second digital signal by performing signal processing including at least a filtering process on the servo signal by using the digital filter. The second electronic circuit acquires a third digital signal by subtracting the second digital signal from the first digital signal. A setting for the signal processing for acquiring the second digital signal is changed on the basis of the third digital signal.

Wireless piezoelectric accelerometers and systems are provided. A wireless piezoelectric accelerometer may comprise a piezoelectric sensing element configured to sense mechanical acceleration and produce an electrical charge signal in response of the sensed mechanical acceleration, a signal processing module (SPM) configured to convert the electrical charge signal into a voltage signal, and process and digitize the voltage signal, and a wireless module configured to modulate and transmit the digitized voltage signal as wireless signals. The piezoelectric sensing element, the SPM and the wireless module are packaged in a casing. The casing comprises a metallic shielding chamber configured to enclose the piezoelectric sensing element. The casing further comprises a non-metallic portion located in relative to the wireless module to allow transmission of the wireless signals. Corresponding wireless piezoelectric accelerometer systems are also provided.

The invention discloses a MEMS sensor detection device and a MEMS sensor system, wherein the MEMS sensor detection device comprises: a readout circuit used for analog signal processing of the output signal of the MEMS sensor to generate detection voltage; a cancellation voltage generation circuit used for generating a gravity cancellation voltage according to the detection voltage, wherein the gravity cancellation voltage and the gravity acceleration are in a positive proportional relationship; a selection circuit used for selecting the detection voltage output in a feedback phase and selecting the gravity cancellation voltage output in a gravity cancellation phase, wherein in one detection period, the feedback phase is located after the gravity cancellation phase; and a feedback circuit used for generating a feedback voltage according to the output voltage of the selection circuit, wherein the feedback voltage is in a positive proportional relationship with the output voltage of the selection circuit. The MEMS sensor detection device and the MEMS sensor system disclosed by the invention can cancel the influence of gravity acceleration and improve the sensitivity of the MEMS sensor system.

The disclosure describes techniques to adjust the geometry of a pendulous proof mass VBA to operate with sufficient signal-to-noise performance while avoiding nonlinear mechanical coupling at specified frequencies. The techniques of this disclosure include adding anchor support flexures to a resonator connection structure, adjusting shape, thickness, and the material of VBA components and of the VBA support structure to both control the frequency of any mechanical resonant modes and to adjust the mechanical mode frequencies away from desired operating frequencies and, in some examples, away from harmonics of desired operating frequencies.