The present disclosure describes a micromechanical resonator comprising a resonator element (40) having a length (l.sub.1) and a width (w.sub.1) that is perpendicular to the length. The resonator element has a length-to-width aspect ratio in a range of 1.8 to 2.2. The resonator element is suspended to a support structure with two or more anchors (41, 43). Each of the two or more anchors is attached to a first location or a second location. The first location is at a shorter side (42) of the resonator element. The first location divides the width (w.sub.1) of the resonator element into a larger portion (w.sub.3) and a smaller portion (w.sub.2) such that a ratio between said smaller portion (w.sub.2) and the whole width (w.sub.1) is in a range of 0.10 to 0.28. The second location is at a longer side (44). The second location divides the length (l.sub.1) of the resonator element into a larger portion (l.sub.3) and a smaller portion (l.sub.2) such that a ratio between said smaller portion (l.sub.2) and the whole length (l.sub.1) is in a range of 0.36 to 0.48.

A microelectromechanical resonator, including a support structure, a resonator element suspended to the support structure, the resonator element including a plurality of sub-elements, and an actuator for exciting the resonator element into a resonance mode. The sub-elements are dimensioned such that they are dividable in one direction into one or more fundamental elements having an aspect ratio different from 1 so that each of the fundamental elements supports a fundamental resonance mode, which together define a compound resonance mode of the sub-element. The sub-elements are further coupled to each other by connection elements and positioned with respect to each other such that the fundamental elements are in a rectangular array configuration, wherein each fundamental element occupies a single array position, and at least one array position of the array configuration is free from fundamental elements.

The present disclosure provides a super-regenerative transceiver with a feedback element having a controllable gain. The super-regenerative transceiver utilizes the controllable gain to improve RF signal data sensitivity and improve RF signal data capture rates. Super-regenerative transceivers described herein permit signal data capture over a broad range of frequencies and for a range of communication protocols. Super-regenerative transceivers described herein are tunable, consume very little power for operation and maintenance, and permit long term operation even when powered by very small power sources (e.g., coin batteries).

An resonant pressure sensor, includes: a housing; a housing-fixed portion that is fixed to the housing; a substrate that includes a substrate-fixed portion that is fixed to the housing-fixed portion and a substrate-separated portion that is separated from the housing-fixed portion and extends from the substrate-fixed portion; a first resonator that is disposed in the substrate-separated portion and that detects a change of a resonance frequency based on a strain in the substrate caused by static pressure applied by the pressure-receiving fluid; and a processor. A pressure-receiving fluid is interposed in a gap between the housing-fixed portion and the substrate and envelops the substrate. The processor measures the static pressure based on the detected change of the resonance frequency.

The present disclosure provides a super-regenerative transceiver with a feedback element having a controllable gain. The super-regenerative transceiver utilizes the controllable gain to improve RF signal data sensitivity and improve RF signal data capture rates. Super-regenerative transceivers described herein permit signal data capture over a broad range of frequencies and for a range of communication protocols. Super-regenerative transceivers described herein are tunable, consume very little power for operation and maintenance, and permit long term operation even when powered by very small power sources (e.g., coin batteries).

A microelectromechanical (MEMS) resonator includes a resonator structure having a plurality of beam elements and connection elements with certain geometry, where the plurality of beam elements are positioned adjacent to each other and adjacent beam elements are mechanically connected to each other by the connection elements, where the geometry of the beam elements or the connection elements varies within the resonator structure.

The present disclosure provides a frequency-converting super-regenerative transceiver with a frequency mixer coupled to a resonator and a feedback element having a controllable gain. The frequency-converting super-regenerative transceiver utilizes the frequency mixer to shift the incoming frequencies, based on a controlled oscillator, to match the frequency of operation of the super-regenerative transceiver. The frequency-converting super-regenerative transceivers described herein permit signal data capture over a broad range of frequencies and for a range of communication protocols. The frequency-converting super-regenerative transceivers described herein are tunable, consume very little power for operation and maintenance, and permit long term operation even when powered by very small power sources (e.g., coin batteries).

A microelectromechanical device having a mobile structure including mobile arms formed from a composite material and having a fixed structure including fixed arms capacitively coupled to the mobile arms. The composite material includes core regions of insulating material and a silicon coating.

A MEMS device includes a first inertial mass system having first drive and sense masses elastically coupled to one another and a second inertial mass system having second drive and sense masses elastically coupled to one another. The first and second drive masses undergo antiphase drive motion along a first axis parallel to the surface of the substrate. First and second sense springs anchor and suspend first and second sense masses spaced apart from the surface of the substrate. The first and second sense springs enable antiphase sense motion of the first and second sense masses along a second axis parallel to the surface in response to an angular rotation about a third axis perpendicular to the surface. The first and second sense springs further enable in-phase sense motion of the first and second sense masses along the second axis in response to a linear acceleration along the second axis.

A microelectromechanical resonator includes a support structure, a resonator element suspended to the support structure, and an actuator for exciting the resonator element to a resonance mode. The resonator element includes a plurality of adjacent sub-elements each having a length and a width and a length-to-width aspect ratio of higher than 1 and being adapted to a resonate in a length-extensional, torsional or flexural resonance mode. Further, each of the sub-elements is coupled to at least one other sub-element by one or more connection elements coupled to non-nodal points of the of said resonance modes of the sub-elements for exciting the resonator element into a collective resonance mode.